USMLE Road Map Inmunology -...
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LANGE
USMLEROAD MAP
IMMUNOLOGYMICHAEL J. PARMELY, PhDProfessorDepartment of Microbiology, Molecular Genetics and ImmunologyUniversity of Kansas Medical CenterKansas City, Kansas
Lange Medical Books/McGraw-HillMedical Publishing Division
New York Chicago San Francisco Lisbon London Madrid Mexico City
Milan New Delhi San Juan Seoul Singapore Sydney Toronto
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USMLE Road Map: Immunology
Copyright © 2006 by The McGraw-Hill Companies, Inc. All rights reserved. Printed in the United States of America. Exceptas permitted under the United States Copyright Act of 1976, no part of this publication may be reproduced or distributed inany form or by any means, or stored in a data base or retrieval system, without prior written permission of the publisher.
1234567890 DOC/DOC 09876
ISBN: 0-07-145298-2
ISSN: 1559-5765
This book was set in Adobe Garamond by Pine Tree Composition, Inc.The editors were Jason Malley, Harriet Lebowitz, and Mary E. Bele.The production supervisor was Sherri Souffrance.The illustration manager was Charissa Baker.The illustrator was Dragonfly Media Group.The designer was Eve Siegel.The index was prepared by Andover Publishing Services.RR Donnelley was printer and binder.This book is printed on acid-free paper.
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C O N T E N T SUsing the Road Map Series for Successful Review . . . . . . . . . . . . . . . . . . . . . . . vii
Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . viii
MECHANISMS AND CONSEQUENCES OF IMMUNE RECOGNITION
1. Innate Immunity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1
2. Adaptive Immunity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14
3. Antigens and Antibodies . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .28
4. Immunoglobulin Gene Expression . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .40
5. Antigen Recognition by Antibody . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .52
6. T Cell Recognition of and Response to Antigen . . . . . . . . . . . . . . . . . . . . . .64
7. Major Histocompatibility Complex . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .77
DEVELOPMENT OF IMMUNE EFFECTOR MECHANISMS
8. Complement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .91
9. B Cell Differentiation and Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .104
10. T Cell Differentiation and Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . .118
11. Regulation of Immune Responses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .130
12. Cytokines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .137
IMMUNITY IN HEALTH AND DISEASE
13. Immune Tissue Injury . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .149
14. Protective Immunity and Vaccines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .164
15. Immune Deficiency States . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .175
16. Autotolerance and Autoimmunity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .192
17. Transplantation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .204
Appendices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .217
Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .219v
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U S I N G T H EU S M L E ROA D M A P S E R I E S
F O R S U C C E S S F U L R E V I E W
What Is the Road Map Series?Short of having your own personal tutor, the USMLE Road Map Series is the best source for efficient review ofmajor concepts and information in the medical sciences.
Why Do You Need A Road Map?It allows you to navigate quickly and easily through your immunology course notes and textbook and prepares youfor USMLE and course examinations.
How Does the Road Map Series Work?Outline Form: Connects the facts in a conceptual framework so that you understand the ideas and retain the information.
Color and Boldface: Highlights words and phrases that trigger quick retrieval of concepts and facts.
Clear Explanations: Are fine-tuned by years of student interaction. The material is written by authors selected fortheir excellence in teaching and their experience in preparing students for board examinations.
Illustrations: Provide the vivid impressions that facilitate comprehension and recall.
Clinical Correlations: Link all topics to their clinical applications, promotingfuller understanding and memory retention.
Clinical Problems: Give you valuable practice for the clinical vignette-basedUSMLE questions.
Explanations of Answers: Are learning tools that allow you to pinpoint yourstrengths and weaknesses.
CLINICALCORRELATION
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Acknowledgments
Special thanks go to my colleagues, Thomas Yankee, Kevin Latinis, Glenn Mackay, and David Cue, for their careful review of selected chapters. I am grateful
to Harriet Lebowitz for her editorial advice and assistance.
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To Tari, for her constant love, patience, and support.To my students, who teach me something new every day.
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USMLE Road Map: Immunology
Copyright © 2006 by The McGraw-Hill Companies, Inc. All rights reserved. Printed in the United States of America. Exceptas permitted under the United States Copyright Act of 1976, no part of this publication may be reproduced or distributed inany form or by any means, or stored in a data base or retrieval system, without prior written permission of the publisher.
1234567890 DOC/DOC 09876
ISBN: 0-07-145298-2
ISSN: 1559-5765
This book was set in Adobe Garamond by Pine Tree Composition, Inc.The editors were Jason Malley, Harriet Lebowitz, and Mary E. Bele.The production supervisor was Sherri Souffrance.The illustration manager was Charissa Baker.The illustrator was Dragonfly Media Group.The designer was Eve Siegel.The index was prepared by Andover Publishing Services.RR Donnelley was printer and binder.
This book is printed on acid-free paper.
INTERNATIONAL EDITION ISBN 0-07-110477-1 Copyright © 2006. Exclusive right by The McGraw-Hill Companies,Inc. for manufacture and export. This book cannot be re-exported from the country to which it is consigned by McGraw-Hill.The International Edition is not available in North America.
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I. Immunity is distinguished by the following features. A. The immune system, which protects the body against microbial invaders and en-
vironmental agents, takes two forms. 1. Innate immunity is available at birth and protects the newborn from patho-
genic microbes.2. Adaptive or acquired immunity arises in the host as a consequence of expo-
sure to a microbe or foreign substance.B. The life-style of the microbe determines the nature of the protective immune re-
sponse.1. Extracellular microbes can be neutralized by antibodies and other soluble im-
mune mediators.2. Elimination of intracellular pathogens requires their recognition by immune
cells that can destroy pathogen-infected host cells.C. Both forms of immunity require a specific recognition of the pathogen or environ-
mental agent and an ability to distinguish it from “self.”D. Innate immunity is a phylogenetically ancient defense mechanism designed for
rapidly recognizing, lysing, or phagocytozing pathogenic microbes and signalingtheir presence to the host. 1. The innate immune system recognizes microbial patterns that are widely dis-
tributed across genera, rather than the discrete antigenic determinants thatcharacterize a particular species of microbe (Chapter 2).
2. Innate immunity does not require prior exposure to the offending agent and isnot altered by a previous encounter with it.
3. Innate immunity is expressed within minutes to hours, representing the first re-sponse of the host to microbial pathogens.
E. The effector mechanisms used by the innate immune system to eliminate foreigninvaders (eg, phagocytosis) are often the same as those used for immune elimina-tion during an adaptive immune response (Chapter 2).
F. Many of the responses we consider to be part of the innate immune system alsoplay a central role in inflammatory responses to tissue injury (Table 1–1).
II. First lines of defense limit microbial survival.A. Physical and chemical barriers provide some of the first lines of innate defense
by preventing microbial attachment, entry, or local tissue survival in a nonspecificmanner.
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C H A P T E R 1
INNATE IMMUNITY
C H A P T E R 1
1
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1. The epithelium of the skin and mucous membranes provides a physical bar-rier.
2. The mucocilliary movement of the lung epithelium and the peristalsis of thegastrointestinal tract move microbes and other foreign agents across mucosalsurfaces and out of the body.
3. The low pH and high fatty acid content of the skin inhibit microbial growth.4. The low pH of the stomach damages essential structures of microbes and limits
their survival.5. Mucins associated with mucosal epithelia prevent microbial penetration and
bind soluble immune factors (eg, antibody molecules).6. A variety of iron-binding proteins (eg, lactoferrin) compete with microbes for
extracellular iron. a. Lactoferrin competes for iron in the extracellular space.b. The Nramp1 gene product enables host cells to acquire the Fe2+ ions neces-
sary to generate reactive oxygen species.c. Nramp2 aids cells in depleting Fe2+ from the phagosome, thus inhibiting
microbial survival.B. The normal flora found at epithelial surfaces provides a biological barrier to
pathogenic microbes that attempt to survive at that site. 1. Normal microbial flora competes with pathogens for nutrients and environ-
mental niches, especially at external body surfaces, such as the skin, intestines,and lungs.
2. Normal flora can induce innate immune responses in the epithelium that limitthe survival of pathogenic microorganisms.
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Table 1–1. Components shared by the innate immune and inflammatory systems.
Component Innate Immune Effects Inflammatory Effects
Phagocytic leukocytes Intracellular killing of microbes Elimination of damaged host cells
Complement system Chemoattraction of leukocytes Chemoattraction of leukocytesLysis, opsonophagocytosis and Increased vascular permeability
clearance of microbes
Fibrinolysis system Complement activation Increased vascular permeabilityLeukocyte chemotaxis Leukocyte chemotaxis
Vascular endothelium Delivery of immune mediators Delivery of inflammatory mediators to to sites of infection sites of damaged tissues
Cytokines Danger signaling Leukocyte adhesion, chemotaxis, and Phagocyte activation uptake of cellular debrisRespiratory burst Phagocyte activationFever Fever
Tissue healing
Neutrophil granules Antimicrobial cationic peptides Extracellular matrix degradation
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III. Pathogens that breach the primary barriers initiate an innate immuneresponse.A. Pathogen-associated molecular patterns (PAMP) are recognized by innate im-
mune cells and soluble mediators. 1. PAMP are often highly charged surface structures or unique spatial arrange-
ments of chemical groups (eg, sugar moieties) that are not seen on host tissues. 2. PAMP are phylogenetically conserved structures that are essential for the sur-
vival of microorganisms.3. Host cell receptors capable of recognizing PAMP are encoded within the
germline and are phylogenetically conserved. a. Relatively few host cell surface receptors are required to recognize a wide
range of pathogens.b. The Toll-like receptor (TLR) family is an important example of phyloge-
netically conserved PAMP-specific host molecules (Table 1–2). 4. A number of soluble host proteins also recognize PAMP.
a. Mannose-binding protein (MBP) (also called mannose-binding lectin)binds to mannose residues of a particular spacing that is seen on microbial,but not mammalian, cells.(1) MBP serves as an opsonin promoting phagocytosis.(2) MBP promotes lysis and phagocytosis of microbes by activating comple-
ment (Chapter 8).b. Lysozyme degrades the peptidoglycan layer of bacterial cell walls.
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Table 1–2. The Toll-like receptor (TLR) family.
TLR Microbial Ligands
TLR1 Bacterial lipopeptides
TLR2 Bacterial peptidoglycan, lipoteichoic acid, lipoarabinomannan, glycolipids,porins
TLR3 Viral double-stranded RNA
TLR4 Bacterial lipopolysaccharide, viral proteins
TLR5 Bacterial flagellin
TLR6 Bacterial lipopeptides; fungal cell wall
TLR7 Viral single-stranded RNA
TLR8 Viral single-stranded RNA
TLR9 Bacterial CpG-containing DNA
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B. The recognition of PAMP activates leukocyte functions.1. Phagocytic leukocytes (blood neutrophils and tissue macrophages) can recog-
nize microbes directly through their mannose receptors, scavenger receptors,Toll-like receptors, or chemotactic receptors.a. The recognition of microbial chemotactic factors directs leukocytes to the
site of infection. (1) Chemotactic factors can be either microbial or host in origin (Table
1–3).(2) Chemotactic factors are recognized by seven transmembrane G protein-
coupled receptors.b. Opsonic receptors on leukocytes recognize host components that have
bound to the surface of microbes.c. Attachment of a microbe to the surface of a phagocyte is followed by its up-
take by membrane invagination (Figure 1–1).(1) The microbe is ingested into a phagosome.(2) The phagosome fuses with an organelle called the lysosome to form a
phagolysosome.d. Intracellular killing of the microbe occurs within the phagolysosome.
(1) Lysosomal hydrolytic enzymes (acidic proteases, lipases, and nucleases)degrade microbial structures.
(2) Leukocyte cytoplasmic granules containing cationic antimicrobial pep-tides (defensins and cathelicidins) fuse with the phagolysosome. (a) These peptides act as disinfectants by disrupting the membrane
functions of microorganisms. (b) Defensins recognize the highly charged phospholipids on the outer
membranes of microbes.(c) Antimicrobial peptides of very similar structure have been found
both in the vernix caseosa covering the skin of newborn humans andthe skin secretions of frogs.
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Table 1–3. Chemotactic factors that attract innate immune cells.
Cell Type Chemotactic Factors
Neutrophil Bacterial lipoteichoic acid Bacterial formyl-methionyl peptidesComplement peptide C5aFibrinogen-derived peptidesLeukotriene B4Mast cell-derived chemotactic peptide NCF-ACytokines: interleukin-8
Macrophage Cytokines: transforming growth factor-β, monocyte chemotacticprotein-1
Lymphocyte Cytokines: macrophage inflammatory protein-1
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(3) In the presence of adequate oxygen, microbe recognition at the phago-cytic cell surface can initiate a respiratory burst, the one electron reduc-tion of molecular oxygen (Figure 1–2). (a) Reactive oxygen intermediates (oxidants and radicals) produced
during this process irreversibly damage essential microbial structures. (b) The reaction begins with the respiratory burst oxidase, a multi-
component membrane-associated enzyme.(c) This oxidase catalyzes the reduction of oxygen (O2) to the radical su-
peroxide (O2•).
(d) The dismutation of superoxide to form hydrogen peroxide (H2O2)is catalyzed by the enzyme superoxide dismutase (SOD).
(e) In the presence of a halide (eg, chloride ion), neutrophil-specificmyeloperoxidase catalyzes the production of hypohalite (eg, hypo-chlorite or bleach) and organic chloramines.
(f) In the presence of ferric ion, the highly reactive hydroxyl radical(OH•) is formed from superoxide and hydrogen peroxide.
CHRONIC GRANULOMATOUS DISEASE (CGD) IS A MUTATION OF THE RESPIRATORY BURST OXIDASE
• Mutations in the subunits of the respiratory burst oxidase (also called NADPH oxidase) can lead to adecreased production of the superoxide radical by phagocytes.
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1
2
3
4
5
Figure 1–1. Opsonophagocytosis and intracellular killing of a pathogen by a phago-cytic cell. 1, Attachment; 2, ingestion (phagosome); 3, phagolysosome; 4, killing, di-gestion; 5, release.
CLINICALCORRELATION
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• Leukocytes of CGD patients fail to produce many of the oxidants that mediate killing of microorgan-isms within the phagolysosome.
• CGD patients are at risk for acquiring opportunistic infections with microbes that would otherwiseshow low virulence in normal individuals.
• Because the phagocytosis of microbes is normal in these patients, some pathogens that are not killedreplicate within the phagolysosome.
• The host attempts to wall off leukocytes containing viable microbes by forming a structure called agranuloma in the lungs and liver.
(4) Oxygen-independent intracellular killing is essential when tissue oxygenis limited, as in deep tissue abscesses.
(5) Some phagocytic cells (eg, tissue macrophages) produce the radical ni-tric oxide (NO•), which can damage microbial structures. (a) NO• is formed from L-arginine and oxygen through a reaction cat-
alyzed by nitric oxide synthase (NOS):
L-arginine-NH2 + NADPH + O2 → NO• + L-citruline + NADP
(b) In macrophages and hepatocytes, the inducible form of NOS(iNOS) catalyzes high level, sustained production of NO• that func-tions as an antimicrobial agent.
(c) Only a few microbes (eg, Mycobacteria and Listeria species) arehighly susceptible to NO•.
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NADPH
NADP
Superoxidedismutase (SOD)
Cl—, myeloperoxidase (MPO)
O2—• (Superoxide)
O2 (Molecular oxygen)
Respiratoryburst oxidase
H2O2 + O2—•
O2 + OH— + OH• (Hydroxyl radical)
(Hydrogen peroxide) H2O2 + O2
HOCl— OCl— (hypochlorite)
R-NH (organic amines)
R-NHCl, R-NCl2 (organic chloramines)
Fe2+
Figure 1–2. The respiratory burst and reactive oxygen intermediates.
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(d) When NO• and O2• combine, they form peroxynitrite (ONOO−),
an especially potent oxidant.2. Epithelial cells also produce the defensins.
a. Defensins limit microbial survival at the mucosal surface of the lung, intes-tine, and genitourinary tract.
b. Defensins are chemotactic for dendritic cells, monocytes, and T lympho-cytes that mediate mucosal defense.
3. Intraepithelial T lymphocytes are found in the skin, lung, and small intestine. a. These cells bear germline gene-encoded antigen receptors (Chapter 6) that
recognize conserved microbial glycolipids.b. Intraepithelial T cells mediate host protection by the secretion of cytokines
that can activate phagocytic cells. 4. Natural killer (NK) cells recognize host cells that are infected with intracellu-
lar pathogens, such as viruses.a. NK cells bear two types of receptors, one for activating the cell and another
for inhibiting its activation.(1) NK cell activating receptors are specific for host and microbial ligands.(2) NK cell inhibitory receptors are specific for major histocompatibility
complex (MHC) molecules that are widely distributed on host tissues(Chapter 7).
(3) When the inhibitory receptor binds host MHC molecules, activation ofthe NK cell is blocked.
(4) When the expression of MHC molecules is decreased on host tissues,NK cells become activated through their activating receptors.
(5) The expression of MHC is often decreased on virus-infected cells.b. Upon activation, NK cells can eliminate microbial pathogens by secreting
cytokines, which activate macrophages.c. NK cells can also lyse infected host cells. d. NK cells also synthesize interferons (Chapter 12) that block the replication
of viruses within infected cells.5. Natural killer T (NKT) cells bear many of the surface receptors present on
NK cells as well as an unconventional form of the T cell antigen receptor(Chapter 6).a. Most NKT cells are specific for microbial glycolipids.b. NKT cells can produce cytokines capable of activating macrophages. c. NKT cells can express cytotoxic activity, although the role of this function
in host defense is still unclear. C. The recognition of microbial pathogens signals “danger” to the host.
1. TLRs (Table 1–2) initiate danger signaling when they bind microbial PAMP. a. Intracellular signal transduction initiated by TLR leads to the activation of
transcription factors.b. For example, TLR4 mediates the recognition of bacterial lipopolysaccha-
rides (LPS), which are common components of the outer membrane ofgram-negative bacteria (Figure 1–3)
c. TLR4 signaling results in the activation of the nuclear factor-κB (NFκB)and AP-1 transcription factors.
d. Among the genes regulated by NFκB and AP-1 are those encoding proin-flammatory cytokines and their receptors, cell adhesion molecules, im-munoglobulins, and antigen receptors.
Chapter 1: Innate Immunity 7
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EXCESSIVE DANGER SIGNALING AND SEPSIS
• Sepsis is a systemic host response to disseminated infection characterized by fever, tachycardia,tachypnea, hemodynamic dysfunction, coagulopathy, and multiorgan damage.
• These processes result from microvascular changes, diminished tissue perfusion, and inadequate tissueoxygenation.
• Sepsis represents excessive danger signaling on the part of the host; soluble and cellular mediators ofinnate immunity are produced in excess.
• The cytokines interleukin (IL)-1, interferon (IFN)-γ, and tumor necrosis factor (TNF)-α are importantearly mediators of sepsis.
• Clinical trials using reagents (eg, antibodies) designed to neutralize any one of these mediators havebeen disappointing, probably owing to mediator redundancy.
2. Cytokine genes are induced by danger signaling and are essential for appropri-ate innate immune responses to infection. a. Cytokines are peptide hormone-like mediators of immunity and inflamma-
tion (Chapter 12).b. Cytokines are produced by a variety of immune cells and induce gene ex-
pression, cell growth, and differentiation.c. Cytokines act through specific cytokine receptors, many of which activate
gene transcription.d. Among the important effects of cytokines are fever, hematopoiesis, chemo-
taxis, increased cell adhesion, changes in blood vessel function, antibodyproduction, and apoptosis (Table 1–4).
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LPS
LPPG PPS
LBP= LPS-bindingprotein
TLR4
CD14
Polysaccharide
Lipid A
Protein
PP OM
CM Host membrane
+
LPS
Danger signal
Figure 1–3. Cellular responses to bacterial lipopolysaccharide (LPS) are mediated by toll-like recep-tor 4 (TLR4). CM, cytoplasmic membrane; LP, lipoprotein; LPS, lipopolysaccharide; OM, outer mem-brane; PG, peptidoglycan; PP, porin protein; PPS, periplasmic space.
CLINICALCORRELATION
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e. The interferons (IFN) are a family of cytokines first noted for their antiviralactivity. (1) IFN-α and IFN-β block virus replication within cells.(2) IFN-γ is a potent activator of macrophages for the killing of intracellular
bacteria and fungi.
DEFECTIVE IFN-γ RECEPTOR FUNCTION LEADS TO OPPORTUNISTICINFECTIONS
• The killing of intracellular microbial pathogens by macrophages requires that the cells be activated bymicrobial or host signals, including cytokines.
• IFN-γ is a potent macrophage activating cytokine that acts on cells through its receptor.
• Point mutations in the human IFN-γ receptor 1 gene impair signaling and macrophage activation forthe killing of intracellular pathogens.
• Life-threatening infections with Mycobacterium and Salmonella species are common and can becomewidely disseminated throughout the body.
• Because the receptors for IFN-α and IFN-β are distinct from those that bind IFN-γ, the affected individu-als do not suffer from increased viral infections.
3. PAMP can activate the complement system of serum proteins.a. Several complement components can recognize highly charged microbial
structures, such as bacterial LPS and surface mannose residues.
Chapter 1: Innate Immunity 9
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Table 1–4. Cytokines that act as danger signals.a
Cytokine Functions Related to Danger Signaling
TNF-α Fever, leukocyte adhesion to endothelium, acute phase proteinsynthesis, respiratory burst, cachexia, cardiac suppression, dissemi-nated intravascular coagulation and shock
IL-1, IL-6 Fever, leukocyte adhesion to endothelium, acute phase proteinsynthesis, B lymphocyte coactivation
Chemokines Lymphocyte and leukocyte migration to sites of infection
IL-4 Lymphocyte coactivation and antibody production
IL-12 Lymphocyte coactivation and cell-mediated immunity
IFN-α, IFN-β Antiviral state, coactivation of macrophages and NK cells, in-creased MHC expression
IFN-γ Coactivation of macrophages, increased MHC expression
aTNF, tumor necrosis factor; IL, interleukin; IFN, interferon; NK, natural killer; MHC, major histo-compatibility complex.
CLINICALCORRELATION
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b. Peptides produced during complement activation mediate host defense andinflammatory functions, such as the chemotaxis of neutrophils, opsoniza-tion, and the lysis of microbial membranes.
c. The activation of mast cell degranulation by complement peptides, calledanaphylatoxins, leads to the release of an additional wave of inflammatorymediators that are stored in mast cell cytoplasmic granules (Chapter 13).
4. The synthesis of acute phase proteins is a response to danger signaling. a. Many acute phase proteins are produced in the liver in response to the cy-
tokines IL-1, IL-6, and TNF-α.b. C-reactive protein (CRP) binds to bacterial surface phospholipids, acti-
vates complement, and serves as an opsonin.c. Increased fibrinogen in plasma increases the erythrocyte sedimentation
rate (ESR), a clinical laboratory test indicative of acute inflammation.5. The coagulation and fibrinolysis systems are activated during acute infections
and inflammation.a. Coagulation serves to localize infection by retaining microbes within a fibrin
clot. b. Peptides derived from fibrinogen during fibrinolysis are chemotactic for
neutrophils.c. Plasmin generated during fibrinolysis can activate the complement system.
DYSREGULATION OF THE COMPLEMENT SYSTEM RESULTS IN ACUTEINFLAMMATION
• Unabated activation of the complement system is potentially harmful to the host due to the produc-tion of inflammatory mediators.
• An important regulator of the classic pathway of complement activation is the protease inhibitor C1inhibitor (C1 Inh).
• Patients with hereditary angioedema (HAE) have significantly decreased levels of plasma C1 Inh.
• Episodic activation of complement in HAE patients results in the production of complement peptidesthat increase vascular permeability.
• The resulting subcutaneous and submucosal edema can lead to airway obstruction, asphyxiation, andsevere abdominal pain.
IV. Danger signals can promote the activation of antigen-specific T and Blymphocytes of the adaptive immune system.A. The nature of danger signaling depends on the type of microbe.
1. Intracellular pathogens often induce innate signals (eg, IL-12) that promote thedevelopment of cellular immunity.
2. Extracellular pathogens often favor induction of antibody responses to micro-bial antigens (Chapter 2).
B. Danger signals activate T and B lymphocytes through their cell surface corecep-tors.1. The complement peptide C3d generated during an innate immune response is
the ligand for the B cell coreceptor CR2. 2. C3d costimulates B cells that have bound antigen through their antigen recep-
tors (Chapter 8).
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CLINICALCORRELATION
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C. Cytokines produced by innate immune cells are important regulators of lympho-cyte activation during adaptive immune responses. 1. IFN-α and IFN-β enhance T lymphocyte responses to microbial antigens by
controlling the expression of MHC molecules (Chapter 7). 2. IL-4 and IL-5 promote the production of certain classes of antibodies by B
lymphocytes.3. IL-12 promotes differentiation of T lymphocytes.
D. Adjuvants are substances that promote adaptive immune responses.1. Most adjuvants act by inducing danger signaling.2. Adjuvants can increase the expression of lymphocyte coreceptors.3. Adjuvants can induce the expression of ligands for lymphocyte coreceptors.4. Adjuvants can induce cytokine production or increased cytokine receptor ex-
pression.
CLINICAL PROBLEMSMs. Jones is a retired secretary who has been admitted to the hospital for treatment of anapparent urinary tract infection. She is administered a third-generation cephalosporin an-tibiotic at approximately 1:00 PM, at which time she has a fever of 101°F, blood pressureof 110/60, and a pulse of 115. The patient tolerates the antibiotic well during the firsthour, but when the nurse returns to her room at 3:00 PM, Ms. Jones’ vital signs have dete-riorated. Her blood pressure has decreased to 80/50, her pulse is now 128, and she nolonger responds when called by name. Her physician concludes that Ms. Jones is septic.
1. Which of the following treatments should be administered immediately?
A. Increase the dose of antibiotic to control the infection.
B. Administer a vasodilator, such as verapamil.
C. Discontinue the antibiotic and administer intravenous fluids.
D. Administer TNF-α to control the infection.
E. Administer complement components to control the systemic inflammatory re-sponse.
Johnny is a 1-month-old healthy child who has not, as yet, received any childhood immu-nizations. He presents with his first episode of otitis media (middle ear infection) that issuccessfully treated with a 3-week course of antibiotics.
2. Which one of the following immune components contributed the most to his clearingthe infectious agent during the first few days of his infection?
A. Antigen receptors on his B lymphocytes
B. Toll-like receptors on his neutrophils
C. Cytokines that promoted antibody formation
D. T cell responses to bacterial antigens
E. Memory B cells
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Recently a patient was identified who had a defect in IL-1 receptor-associated kinase(IRAK)-dependent cellular signaling associated with her TLR4 receptor.
3. Which one of the following groups of pathogens would be expected to cause recurrentinfections in this individual?
A. Retroviruses, such as HIV-1
B. Fungi that cause vaginal yeast infections
C. Gram-negative bacteria
D. Gastrointestinal viruses
E. Insect-borne parasites
Anaerobic bacteria are often cultured from infected deep tissue abscesses.
4. If you were a neutrophil recruited to an anaerobic site to kill such a bacterium, whichof the following substances would you most likely use?
A. IL-12
B. Nitric oxide
C. Interferon-αD. Respiratory burst oxidase
E. Cathelicidin
You are part of a research team that is attempting to design a better vaccine for the preven-tion of tuberculosis, which is caused by the intracellular bacterial pathogen Mycobacteriumtuberculosis. One of your colleagues suggests that you include an adjuvant in the vaccineformulation.
5. Based on your knowledge of protective immunity to this pathogen, which one of thefollowing would be a reasonable choice of an adjuvant component?
A. A cytokine that promotes an IFN-γ response to mycobacterial antigens
B. The complement peptide C3d, which will ensure adequate antibody production.
C. Interleukin-10
D. Bacterial lipopolysaccharide
E. Lactoferrin
ANSWERS
1. The answer is C. Sepsis is a systemic inflammatory response to infection that resultsfrom exposure of the host to diverse microbial components expressing PAMP. Withantibiotic treatment, large quantities of bacteria die and release these proinflammatorycomponents, including bacterial LPS. The most important initial step is to discontinueantibiotic treatment until the septic episode has passed. Fluids are given to correct hy-potension, and severe cases may need to be treated with pressors (eg, dopamine) to
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maintain blood pressure. The patient’s symptoms (hypotension, tachycardia, and hy-poxia) are indicative of extreme vasodilation, the loss of fluid to the extravascular tis-sues, and inadequate tissue oxygenation. TNF-α is thought to be a major centralmediator of systemic septic shock. The activation of complement would be expected toaggravate the systemic inflammatory response by further inducing vascular changes, hy-potension, and hypoxia.
2. The correct answer is B. In a child of this age who has not previously been exposed tothis bacterial pathogen or immunized against its antigens host defense is primarily me-diated by the innate immune system. Neutrophils play a central role in clearing bacteriaand recognize molecular patterns on these pathogens via their TLR. By contrast, T andB lymphocytes mediate adaptive immunity (eg, antibody formation), which requiresseveral days to develop in an immunologically naive individual.
3. The correct answer is C. TLR4 is the signaling receptor for bacterial LPS, a componentof the outer membrane of gram-negative bacteria. Patients with impaired TLR4 signal-ing are at risk for recurrent, life-threatening infections with gram-negative bacteria.TLR4 is not known to mediate protective responses to viruses, fungi, or parasites.
4. The correct answer is E. In the absence of molecular oxygen, neither reactive oxygenspecies (eg, superoxide) nor NO can be produced in sufficient quantities to kill bacte-ria. Under these conditions, the neutrophil must rely on oxygen-independent killingmechanisms, such as the action of its antimicrobial granule peptides.
5. The correct answer is A. Any cytokine that would promote the development of anti-gen-specific, IFN-γ-producing lymphocytes would probably have a favorable effect. Pa-tients who cannot produce IFN-γ are at risk for developing mycobacterial infections.Interleukin-12 is a good example of an IFN-γ-inducing cytokine. Because thispathogen resides within tissue macrophages in chronically infected individuals,macrophage activation for intracellular killing is an essential protective response to in-fection.
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I. Adaptive immunity is distinguished by the following features. A. Unlike innate immunity, adaptive immunity is an acquired response to antigen
that is initiated by the recognition of discrete antigenic determinants on foreign in-vaders (Table 2–1).
B. The host is changed by its exposure to antigen; the individual becomes “immu-nized” against a particular antigen. 1. The primary response to an antigen takes several days and requires antigen
recognition, the activation and proliferation of T and B lymphocytes, and thedifferentiation of these cells into populations of effector lymphocytes.
2. Sets of antigen-specific memory T and B cells are also generated that mediatesecondary responses to the antigen at a later time.
3. The long-term maintenance of memory and the return of lymphocytes to anonactivated state are carefully controlled.
C. T and B lymphocytes are the primary mediators of adaptive immunity and recog-nize antigenic determinants by their cell surface antigen receptors.1. Receptors with specificity for autoantigens are expressed during the develop-
ment of the adaptive immune system. a. Most lymphocytes with autoreactive receptors are deleted. b. Some autoreactive lymphocytes survive, but their activation is carefully con-
trolled in the periphery. 2. Whereas B cell receptors predominantly recognize soluble native antigens,
T cell receptors recognize foreign antigens only on the surfaces of other host cells. D. Many of the effector cells and molecules that mediate antigen clearance in adap-
tive immunity are the same as those that mediate protective innate immune re-sponses.
II. Primary and secondary adaptive immune responses differ.A. Evidence of a primary immune response to an antigen appears only after an ini-
tial lag phase (Figure 2–1). B. Antibody produced following active immunization is specific for the immuniz-
ing antigen. C. The host has enormous diversity in its capacity to respond to different antigens.
1. Estimates of the number of different antigen receptors potentially expressed byB or T cells range from 108 to 109.
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C H A P T E R 2C H A P T E R 2
ADAPTIVE IMMUNITY
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2. A diverse immune repertoire exists at birth in human beings and undergoesfurther changes based on the immunological experiences of the individual.
D. Immunity mediated by lymphocytes or the antibodies they produce can be trans-ferred from an immune host to a naive recipient.1. The transfer of antibodies is called passive immunization.2. The transfer of immune cells is called adaptive immunization.
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Table 2–1. Comparison of the properties of innate andadaptive immunity.
Property Innate Immunity Adaptive Immunity
Time Immediate Delayed
Recognition Conserved, widely Discrete, diverse antigenic distributed microbial determinantscomponents Antigen presentation
Cells Many cells: phagocytes, Lymphocytessome lymphocytes, epithelial cells
Response Uptake and clearance, Clearance, lysis, memorydanger signaling
Seru
m a
ntib
ody
conc
entr
atio
n
0 14 0 6 14
Time, days
0
0.1
1.0
10
100
Anti
body
con
cent
rati
on in
ser
um,
unit
s pe
r m
l
1° Ag 7 7 14 2114
Time after immunization, days
2° Ag
Primary anti-Bresponse
Primary anti-Aresponse
Secondary anti-Aresponse
Antigen A Antigen A+ Antigen B
Primaryresponse
Secondaryresponse
IgG
IgM
IgG
IgMlag
Total
Total
Figure 2–1. Time course of a typical primary and secondary antibody response. Ig, immunoglobulin.
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NEWBORNS ACQUIRE MATERNAL IMMUNITY BY PASSIVE IMMUNIZATION
• Newborns are passively immunized when their mothers transfer protective antibodies to them eitheracross the placenta or through the colostrum and milk.
• The relative importance of these two routes in various mammalian species is determined by the struc-ture of their placentas.
• Human beings have two cell layers separating fetal and maternal blood and actively transport mater-nal antibodies across the placenta.
• The class of antibody that is transported is immunoglobulin G (IgG) (Chapter 3) and it provides sys-temic antibody protection to the newborn.
• Colostral antibodies in humans are predominantly immunoglobulin A (IgA) and they protect the new-born intestinal tract from infectious pathogens.
• By contrast, the fetal calf receives no immunoglobulin from its mother during gestation, and is highlydependent upon suckling colostrum containing IgG antibodies during its first few days of life.
E. Secondary responses to an antigen in immune animals differ from primary adap-tive immune responses (Figure 2–1).1. The lag period is shorter for the secondary response.2. The overall amount of antibody produced is greater in the secondary response.3. The class of antibody differs in the two responses.
a. Primary antibody responses are mostly immunoglobulin M (IgM). b. Secondary antibody responses consist primarily of non-IgM classes, espe-
cially IgG. c. The change that occurs in the class of antibody produced is called isotype
switching and results in new functions being associated with the same anti-body specificity (Chapter 3).
d. The longer duration of the secondary response reflects the large number ofmemory B cells that are activated and the longer half-life of IgG in circula-tion compared to IgM.
III. Cells of the adaptive immune system are found in discrete lymphoidtissues and organs. A. Primary lymphoid organs are organs in which the antigen-independent develop-
ment of lymphocytes occurs.1. The bone marrow is a major site of hematopoiesis and lymphopoiesis in both
young and adult animals.2. Under the influence of the bone marrow stromal cells and growth factors, the
various blood lineages develop.
HEMATOPOIETIC GROWTH FACTORS CAN CORRECT IMMUNE DEFICIENCIES
• Cyclic neutropenia is a 3-week oscillating deficiency in the production of blood neutrophils that canleave patients at risk for infections (Table 2–2).
• The inherited form of the disease results from point mutations in the neutrophil elastase gene, suggest-ing that this protease participates in myelopoiesis.
• Treatment with colony-stimulating factor for granulocytes (CSF-G) replenishes neutrophil num-bers in the blood during the neutropenic phase.
• By contrast, severe congenital neutropenia, which is due to a mutation in the gene for the receptorfor CSF-G, is not responsive to CSF-G therapy.
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• Colony-stimulating factors for other hematopoietic progenitor cells, including erythropoietin and in-terleukin-3, have become standard treatments for many selective hematopoietic deficiencies.
3. Lymphocytes are also derived from a common self-renewing hematopoieticstem cell that gives rise to all blood cell lineages. a. In the appropriate inductive microenvironment, the pluripotent stem cell
differentiates into a lymphoid progenitor cell (LPC).b. The LPC can become a progenitor T (pro-T) cell or a progenitor B (pro-
B) cell.c. In human beings, B lymphopoiesis occurs primarily in the bone marrow
(Chapter 9), but T lymphocyte development moves to the thymus at thepro-T cell stage (Chapter 10).
d. An important process that accompanies T and B cell differentiation in thebone marrow and thymus is the expression of surface antigen receptors.
DIGEORGE SYNDROME PATIENTS LACK A THYMUS
• DiGeorge syndrome is a congenital condition arising from defective embryogenesis of the third andfourth pharyngeal pouches.
• Patients with DiGeorge syndrome show abnormalities in the structure of their major blood vessels,heart, and parathyroids and evidence thymic hypoplasia.
• Immunological abnormalities include severe lymphopenia (Table 2–2) at birth and early onset infec-tions by opportunistic viruses and fungi.
• Antibody levels are normal at birth due to the transplacental passage of antibodies from the mother inutero.
• The immune deficiencies of these children can be cured by thymic transplantation from a suitabledonor.
B. Secondary lymphoid organs are sites at which the host mounts adaptive immuneresponses to foreign invaders.
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Table 2–2. Congenital leukocyte and lymphocyte deficiencies affecting immunity.
Cell Type Subsets Normal Cell Numbers Congenital Deficiencies (103 per µL) in the Affecting the Number of Blood of Adults Cells in the Periphery
Leukocytes Total 4–11Neutrophils 2–7 Neonatal and cyclic
neutropeniaMonocytes 0.2–1.2
Lymphocytes Total 1.0–4.8 Severe combined immune deficiency
B cells 0.1–0.7 X-linked agammaglobulinemia
T cells 0.5–3.6 DiGeorge syndromeCD4+ T cells 0.2–1.8 MHC class II deficiencyCD8+ T cells 0.1–0.9 MHC class I deficiency
CLINICALCORRELATION
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1. Secondary lymphoid organs and tissues include the spleen, lymph nodes,Peyer’s patches, and widely distributed lymphoid follicles.
2. The lymph node is an encapsulated organ that receives antigens from subcuta-neous and submucosal tissues via its afferent lymphatics (Figure 2–2). a. B cells are concentrated in discrete primary and secondary follicles within
the cortex of lymph nodes, where they undergo antigen-driven differentia-tion.
b. Memory B cells develop within the germinal centers of the cortex.c. T cells are located primarily in the diffuse cortex (or paracortex), where
they associate with dendritic cells. d. Cells enter the lymph nodes in large numbers by crossing the high endothe-
lial layer of postcapillary venules located in the diffuse cortex. e. Terminally differentiated B cells, called plasma cells, are found in the
medullary cords, where they produce large amounts of antibody duringtheir limited life-span.
f. Secreted antibodies exit the lymph nodes via the efferent lymphatics andeventually enter the blood stream.
3. The spleen receives antigens through the blood circulation and contains areasfunctionally equivalent to those of the lymph nodes (Table 2–3).
4. Other important peripheral lymphoid tissues include the Peyer’s patches andsubmucosa of the small intestine, which are sites in which mucosal antibody re-sponses are induced (Chapter 9).
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Afferent lymphatic
Diffuse cortex
Medullarycord
Efferent lymphatic
High endothelialvenule
Capsule
Artery
Germinalcenter
Follicle
Vein
Figure 2–2. Schematic structure of a lymph node.
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C. A recirculating lymphocyte pool of long-lived small lymphocytes continuallytravels between the various lymphoid tissues by a route that includes the bloodand lymph (Figure 2–3). 1. Recirculating lymphocytes enter the lymph nodes from the blood by crossing
the high endothelial venules in the diffuse cortex. 2. The cells exit the lymph nodes via the efferent lymphatics and migrate via the
common thoracic duct to the blood stream. 3. Lymphocytes can exit the blood circulation by crossing the endothelium at
many locations.
IV. The clonal selection theory of adaptive immunity proposes that anantigen selects and activates the appropriate clone of lymphocytes from apreformed diverse pool. A. The theory predicts the following:
1. Each lymphocyte is precommitted to a particular antigen prior to encounteringthat antigen (Figure 2–4).
2. Lymphocytes recognize their antigens with cell surface antigen receptors.3. The receptor on a given lymphocyte is specific for only one antigen.4. Antigen binding to the receptor induces the expansion of a clone of cells, all
with identical receptor specificity.5. The antigen receptor on a given lymphocyte is uniform and identical to the an-
tibody molecules secreted by the cell.B. The theory has proven correct for both B and T lymphocytes with the following
exceptions:1. The B cell antigen receptor is actually a modified form of an antibody molecule
(Chapter 4).2. The T cell antigen receptor is not an antibody molecule (Chapter 6).3. T cells do not secrete large amounts of their receptor molecules.
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Table 2–3. Comparison of analogous structures in the lymph nodes and spleen.
Lymph Node Spleen Function
Follicles Follicles B cell activation and differentiation
Diffuse cortex Periarteriolar T cell activation and differentiationlymphoid sheath
Medullary cords Red pulp cords Antibody production by plasma cells
High endothelium Marginal sinuses Site of entry of lymphocytes from the of postcapillary recirulating lymphocyte poolvenules
Afferent lymphatics Marginal sinuses Site of entry of antigens
Efferent lymphatics Marginal sinuses Point of exit of effector lymphocytes to join the recirculating pool
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C. The production of a pool of memory lymphocytes ensures that a higher concen-tration of specific antibody is produced in a more rapid fashion during a sec-ondary response.
D. Because lymphocytes with receptors specific for autoantigens (“forbiddenclones”) are mostly deleted or inactivated during their differentiation, autoim-munity is rare.
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Lymph nodewithout antigen
Lymph nodewith antigen
Peripheral tissue site ofinfection/inflammation
High endothelialvenule
Bloodvessel
Bloodvessel
Bloodvessel
Common thoracic duct
Efferentlymphaticvessel
Efferentlymphaticvessel
Afferentlymphaticvessel
Lymphatic vessel
Microbes
Activated T cellNaive T cell
Antigen presenting cell
Peripheral blood vessel
Figure 2–3. Route of recirculation of lymphocytes from blood to lymph.
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PERNICIOUS ANEMIA
• Pernicious anemia (PA) is an organ-specific autoimmune disease characterized by a decreased ab-sorption of dietary vitamin B12.
• Vitamin B12 is normally absorbed in the ileum as a complex with intrinsic factor, a protein synthesizedby gastric parietal cells.
• Failure to absorb vitamin B12 in PA results from an autoimmune attack on gastric parietal cells and theclearance of intrinsic factor by autoantibodies.
• The resulting vitamin B12 deficiency results in impaired erythropoiesis (megaloblastic anemia).
V. Lymphocytes express antigen receptors.A. The antigen receptor complexes of T and B lymphocytes are similar in structure
and function (Figure 2–5). 1. The B cell receptor (BCR) for antigen consists of a membrane form of anti-
body and the accessory peptides Igα and Igβ.a. The BCR recognizes discrete antigenic determinants (epitopes) on soluble
antigens.
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Bone marrowAntibody 3
Peripheral lymphoid tissue
Stemcell
Gene rearrangement
Antigen-independent differentiation Antigen-dependent differentiation
ImmatureB cells
MatureB cells
1
2
3
4 4
2
13
3
3
3
3 3
3
3
3
3
3
3
3
3
3
Antigen 3Memorycell
Plasmacell
Figure 2–4. Clonal selection theory of adaptive immunity.
CLINICALCORRELATION
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B. Igα and Igβ mediate antigen-induced transmembrane signaling in B cells.1. The T cell receptor (TCR) complex consists of antibody-like peptides and sig-
naling peptides.a. Unlike the BCR, the TCR can recognize only foreign antigens that are dis-
played on the surfaces of other cells. (1) T cells recognize surface-bound small peptides that are derived by prote-
olysis from native protein antigens.(2) The TCR recognizes determinants of the foreign peptide plus host cell
surface molecules called major histocompatibility complex (MHC)molecules.
(3) The cells on which these processed foreign peptides are displayed are col-lectively referred to as antigen-presenting cells (APC).
b. The MHC regulates antigen recognition by T cells.(1) Only peptides that can bind to the host’s MHC molecules are recog-
nized by T cells.(2) Two classes of MHC molecules control T cell antigen recognition in this
fashion (Figure 2–6). (a) MHC class I is expressed on nearly all nucleated cells. (b) MHC class II is expressed on dendritic cells, macrophages, and B
cells. (3) MHC restriction ensures that T cells will be activated by antigen only in
proximity to other host cells.(a) T helper (Th) cells recognize antigen presented by MHC class II-
expressing dendritic cells (DC), B cells, and macrophages.
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T cell receptor B cell receptor
Signal transduction
Antigen-presenting cell
MHC
TCR
Antigenicpeptide
CD3
ξ
Signal transduction
Membrane Ig
Igα Igβ
Antigen
T cell B cell
Figure 2–5. Antigen receptors on B and T lymphocytes. MHC, major histocompati-bility complex; TCR, T cell receptor; Ig, immunoglobulin.
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(b) Cytotoxic T (Tc) cells recognize antigen-expressing (eg, viral anti-gens), MHC class I-expressing host cells.
c. The signaling peptides of the TCR are collectively referred to as CD3.d. The TCR complex is first expressed during T cell development in the thy-
mus (Chapter 10).
T CELL DEFICIENCIES DUE TO ABNORMAL CD3 EXPRESSION
• Mutations in two different CD3 peptides (CD3γ and CD3ε) have been described that decrease TCR ex-pression.
• These patients show few peripheral T cells, susceptibility to viral and fungal infections, and autoimmu-nity.
• In addition to treatment for infections, these patients are candidates for hematopoietic stem cell trans-plantation, which can correct the defects.
• This and other congenital immune deficiencies are described in detail at the Online Mendelian Inheri-tance in Man web site maintained by the National Library of Medicine (www.ncbi.nlm.nih.gov/omim).
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Endocytosis ofextracellularprotein
Antigen uptakeor synthesis
Antigenprocessing
MHC biosynthesisand loading
Peptide-MHCassociation
Anigenpresentation
Class IIMHC
Class IMHC
ER
ER
Cytosolicprotein
Peptides incytosol
Proteasome
TAP
Invariantchain (Ii)
Antigen-presentingcell
Antigen-presentingcell
CD4+
T cell
CD8+
CTL
Clas
s I M
HC
path
way
Clas
s II
MH
C pa
thw
ay
Figure 2–6. Schematic of antigen presentation. MHC, major histocompatibility complex; ER, endo-plasmic reticulum; CTL, cytotoxic T lymphocyte; TAP, transporter of antigenic peptide.
CLINICALCORRELATION
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C. Antigen presentation requires the processing and MHC-dependent display ofantigenic determinants (Figure 2–6). 1. Any nucleated cell can potentially present peptide antigens through MHC class I.
a. T cells that recognize peptides + MHC class I bear a distinguishing cell sur-face coreceptor called CD8.
b. Most CD8+ T cells are cytotoxic.2. DC, B cells, monocytes, and macrophages express MHC class II and can pre-
sent antigenic peptides via class II molecules.a. T cells that recognize peptides + MHC class II bear a distinguishing cell sur-
face coreceptor called CD4.b. Most CD4+ T cells secrete cytokines that regulate the activation of other im-
mune cells.
VI. Lymphocytes bear a number of additional cell surface molecules thatcontrol their activation, migration, or effector functions.
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Table 2–4. Properties of CD markers.a
CD Category Examples Expression Major Functions
Antigen presentation CD1 Dendritic cells Presents glycolipid antigens
Adhesion molecules CD18 Leukocytes Adhesion to endothelium
Coreceptors CD4 T cells Coactivates with TCR-CD3
Cytokine receptors CD25 B cells Binding of IL-2
Ig-binding receptors CD32 Macrophages Binding IgG–antigen complexes
Signal transduction CD3 T cells Mediates signaling of TCR
Homing receptors CD62L B and T cells Homing to lymph nodes
Death-inducing CD120 Many cells TNF-α-induced apoptosisreceptors
Enzymes CD45 T cells Phosphatase; regulates TCR signaling
Complement CD55 Many cells Regulates complement receptors activation
Blood group markers CD240D Erythrocytes Major Rh antigen
aFor a more complete list of CD markers, see Appendix I. TCR, T cell receptor; IL-2, interleukin 2;IgG, immunoglobulin G; TNF, tumor necrosis factor.
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A. Coreceptors on lymphocytes promote signaling through the TCR and BCR. 1. Coreceptors lower the threshold for lymphocyte activation through their anti-
gen receptors. 2. Coreceptors can act by modulating intracellular signaling pathways or increas-
ing the expression of other receptors.B. T and B cells express a range of cytokine receptors that provides additional sig-
nals for cell activation. C. Receptors that bind IgG molecules present in antigen–antibody complexes (Fc
receptors) typically inhibit B cell activation.D. Cell adhesion molecules mediate lymphocyte migration between and within tis-
sues and increase the binding between lymphocyte subsets.E. One method for cataloging cell surface molecules is the cluster of differentiation
(CD) scheme that assigns a CD number to each unique cell surface molecule(Table 2–4, Appendix I, and www.hlda8.org/).
PHENOTYPING OF LYMPHOCYTE SUBSETS
• Human lymphocyte subsets are routinely enumerated in the clinical laboratory by a technique knownas flow cytometry (Chapter 5).
• Monoclonal antibodies to the CD markers of interest (Table 2–4) are labeled with a fluorochrome andused to stain cells.
• The flow cytometer detects labeled antibody binding to the cell and thereby enumerates surface CDmolecules on blood cells or cells prepared from solid tissues (eg, tumors).
• Abnormal lymphocyte numbers are associated with congenital or acquired immune deficiencies, infec-tions, and neoplastic conditions.
• Leukemias and lymphomas can be typed and staged by defining the CD markers they express.
CLINICAL PROBLEMSA 2-month-old male child presents with thrush (a yeast infection in the oral cavity), diar-rhea, and failure to thrive. His complete blood count reveals a severe lymphopenia. Flowcytometry demonstrates a very low number of CD3+ lymphocytes in his blood, but nor-mal numbers of membrane IgM+ lymphocytes when compared to age-matched controls.
1. Which one of the following represents the most likely underlying disease in this child?
A. X-linked agammaglobulinemia (XLA)
B. DiGeorge syndrome
C. Neonatal neutropenia
D. Myeloperoxidase deficiency
E. Aplastic anemia
A patient has a history of recurrent pneumonias that reappear within a week followingcompletion of antibiotic therapy. She is found to have a deficiency in the expression ofCD18.
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2. Which of the following two clinical abnormalities would you most expect to find insuch a patient? More than one answer may be correct.
A. Lymphopenia
B. Leukocytosis
C. Recurrent viral infections
D. Recurrent bacterial infections
E. Abnormal BCR cell signaling
F. Agammaglobulinemia
G. Reduced T lymphocyte receptor expression
3. Which of the following is a “pattern recognition receptor”?
A. BCR
B. Interleukin-1 receptor
C. Fc receptor
D. CD4
E. Mannose receptor
A patient presents with a lymphocytosis and enlarged lymph nodes, and a biopsy of thebone marrow is performed. Ninety percent of the patient’s bone marrow cells stain with afluorescent antibody specific for CD3.
4. Which of the following is a reasonable differential diagnosis?
A. AIDS
B. DiGeorge syndrome
C. T cell leukemia
D. Cytomegalovirus infection
E. This is a normal laboratory finding.
Patients with deficiencies in antibody production can often present with the same types ofinfections as are seen in patients with phagocytic cell deficiencies.
5. Which of the following statements best explains this observation?
A. Autoantibodies can remove phagocytic cells from the blood circulation.
B. Plasma cells are the direct progenitors of certain phagocytic cells.
C. Macrophages can differentiate into antibody-producing plasma cells.
D. Antibodies are important opsonins that promote microbe recognition by phago-cytes.
E. Antibodies are essential for the continued production of phagocytic cells by thebone marrow.
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ANSWERS
1. The correct answer is B. The finding of low lymphocyte counts in the blood (lym-phopenia) affecting only T cells suggests a deficiency in cell-mediated immunity sec-ondary to decreased T cell numbers, such as in thymic dysplasia (DiGeorge syndrome).This would be expected to lead to opportunistic infections by intracellular pathogens,such as the yeast Candida albicans.
2. The correct answers are B and D. The CD18 gene encodes for an adhesion molecule,and patients with decreased CD18 expression show poor leukocyte adhesion to the vas-cular endothelium. The increase in leukocyte production seen during infections resultsin an increased number of leukocytes in the blood (leukocytosis). The resulting de-creased leukocyte migration to infection sites impairs clearance of extracellular bacterialpathogens.
3. The correct answer is E. The mannose receptor recognizes the spatial arrangement ofmannose residues that is found only on microbial surfaces.
4. The correct answer is C. Finding large numbers of CD3+ cells in the bone marrow ismost likely indicative of neoplastic T cells (leukemia), because CD3 is normally ex-pressed only after the pro-T cell migrates to the thymus.
5. The answer is D. Antibodies of certain classes can bind to microbial surface antigensand mark them for uptake by phagocytic cells. This is because phagocytes bear opsonicreceptors that bind antibody-coated particles and signal an increased rate of uptake.Thus, patients who lack certain antibodies will show diminished phagocytic cell func-tion due to impaired opsonophagocytosis.
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I. AntigensA. An antigen is a substance that can elicit an adaptive immune response. B. Most natural and medically important antigens are macromolecules or substances
that can bind covalently to them. C. Naturally occurring antigens include proteins, polysaccharides, lipids, and nucleic
acids.D. The region of an antigen that is recognized by the immune system is called an
antigenic determinant or epitope.E. Antigens generally have two properties.
1. Immunogenicity is the capacity to induce an immune response.a. Immunogenicity is determined by the molecular mass, molecular complex-
ity (number of potential determinants), and conformation of an antigen.b. A high degree of phylogenetic disparity between an antigen and the host
generally promotes immunogenicity. 2. Antigenicity is the ability to bind specifically to antibody molecules or antigen
receptors on lymphocytes. 3. A hapten is a molecule that is antigenic, but not immunogenic.
a. A hapten generally has a molecular mass of less than 10,000 Da. b. A hapten can become immunogenic if it is covalently attached (conjugated)
to a carrier molecule. c. Some haptens can cause allergic dermatitis if they bind to proteins in the
skin. d. Conjugating microbial epitopes (haptens) to carrier proteins is an effective
approach to producing highly immunogenic vaccines.
PENICILLIN IS A HAPTEN THAT CAN INDUCE IMMUNE-MEDIATED TISSUEDAMAGE
• Penicillin G is a small drug (MW 356) that can bind to a variety of host proteins, including those on thesurface of human erythrocytes.
• Antipenicillin antibodies can be produced that cause autoimmune hemolytic anemia.
• The Coombs test is used to determine if an anemia has an immune basis by determining whether im-munoglobulin G (IgG) antibodies are present on the patient’s erythrocytes.
• The treatment of Coombs-positive anemias includes discontinuing the drug (hapten) and transfusingnormal ABO-matched erythrocytes.
NC H A P T E R 3C H A P T E R 3
ANTIGENS AND ANTIBODIES
28
CLINICALCORRELATION
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F. Antigenic determinants that bind to antibodies and B cell antigen receptors areoften different from those that bind to T cell antigen receptors (Table 3–1).1. Determinants recognized by antibodies or B cells are typically found on the ex-
posed hydrophilic surface of an antigen molecule.2. Antigens that bind to the T cell antigen receptor typically do not possess their
native conformation.a. Most antigens that stimulate T cells are proteins.b. For a protein to be recognized by a T cell it must be degraded into peptides
and presented by an antigen-presenting cell (APC). c. T cell determinants are not limited to surface exposed regions of proteins
and can be derived from internal hydrophobic protein domains.
II. AntibodiesA. All antibodies are immunoglobulins (Igs).B. Igs are a homologous family of proteins with considerable structural heterogene-
ity.C. Most Igs migrate in the “gamma” region upon serum protein electrophoresis
and are therefore called γ-globulins (Figure 3–1).
INTRAVENOUS IMMUNOGLOBULIN (IVIG)
• Immunoglobulins (γ-globulins) are routinely given to patients for the prevention or treatment of vari-ous diseases.
• IVIGs are often used to treat congenital antibody deficiencies and must be given repeatedly.
• Because IVIG is greater than 95% IgG, its primary immune benefit in immunodeficient patients is toprovide protection against extracellular microbial pathogens or their toxic products.
• Some infectious diseases in normal individuals, such as rabies and hepatitis, can be effectively pre-vented with γ-globulins prepared from specific immune donors that are administered shortly after asuspected infection.
D. The structure of antibodies was first determined by studying Igs purified from thesera of patients with multiple myeloma.
Chapter 3: Antigens and Antibodies 29
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Table 3–1. Comparison of the antigenic determinants recognized by B and T lymphocytes.
Property B cells T cells
Conformation dependent + −
Hydrophillic/hydrophobic Hydrophillic Hydrophillic and hydrophobic
Location of determinants Surface Surface and internal
MHC dependent − +
Examples Native proteins and Peptidescarbohydrates
CLINICALCORRELATION
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1. Multiple myeloma is a malignancy of a clone of Ig-producing plasma cells.2. Myeloma Igs (also called M proteins) are monoclonal and structurally homo-
geneous.3. All M proteins belong to one of five structurally distinct Ig classes or isotypes. 4. The most frequently encountered isotype among myeloma proteins is IgG.
a. IgG molecules have the molecular formula H2L2 and show bilateral sym-metry (Figure 3–2).(1) Each IgG molecule contains two identical heavy (H) chains.(2) The H chains of IgG molecules are designated γ chains and have a mo-
lecular mass of approximately 50,000 Da. (3) H chains are linked to one another by inter-chain disulfide bonds.(4) Each IgG molecule contains two identical light (L) chains, each with a
molecular mass of approximately 25,000 Da. (5) L chains are covalently linked to H chains by inter-chain disulfide
bonds. b. Intra-chain disulfide bonds in both H and L chains maintain protein folds
that define Ig domains of approximately 110 amino acids in length (Figure3–2).
c. There are two such domains in L chains and four in γ H chains.5. There are a total of five classes or isotypes of human Ig, designated IgG, IgM,
IgA, IgE, and IgD (Table 3–2).a. Each Ig has the core molecular H2L2 structure and contains H chains
unique to that isotype. b. IgG, IgM, IgA, IgE, and IgD have γ, µ, α, ε, and δ, H chains, respectively.
(1) γ, α, and δ chains have molecular masses of 50,000–60,000 Da. (2) µ and ε chains, which have an additional Ig domain, have molecular
masses of 65,000–70,000 Da (Table 3–2).
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–+
Globulins
Albumin
α
γ
βAbso
rban
ce
Migration distance
Immune serum
Normal serum
Figure 3–1. Serum protein electrophoresis.
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c. The IgG class is further subdivided into the IgG1, IgG2, IgG3, and IgG4 sub-classes.
d. The IgA class is further subdivided into the IgA1 and IgA2 subclasses.6. All Igs can occur in two forms, secreted and membrane bound.7. There are two human L chain types, termed κ and λ.
a. In any one immunoglobulin molecule, both L chains are either κ or λ. b. The overall κ:λ ratio for the Igs found in human serum is approximately
60:40. 8. Oligosaccharides are covalently attached to the carboxyl-terminal half of H
chains, especially within µ and ε chains.
MULTIPLE MYELOMA
• Patients with multiple myeloma can have extremely high levels of Igs in their plasma that are often firstdetected by serum protein electrophoresis (Figure 3–1).
• Because their cancers are monoclonal and have a homogeneous charge, the abnormal M protein ap-pears on electrophoresis as a “spike.”
• Each M protein has a single H chain class and a single L chain type.
• Many patients with myeloma also have high concentrations of Ig L chains in their urine, which are pro-duced in excess by their myeloma cells.
• In a given patient, these Bence–Jones proteins are monoclonal, dimeric, and either κ or λ, but notboth.
• Finding a significant departure from the normal 60:40 κ:λ ratio in serum or urinary L chains is diagnos-tic of a monoclonal gammopathy, such as myeloma.
E. IgM and IgA molecules can exist as multimers (Figure 3–3).1. Serum IgM is a pentamer of the core H2L2 structure that is joined together by
intersubunit disulfide bonds and stabilized by a 15-kDa joiner (J) chain.
Chapter 3: Antigens and Antibodies 31
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CLINICALCORRELATION
Hinge
CL domainCH1 VH domainVL domain VH domain
Antigenbindingsite
Antigenbindingsite VLdomain
Carbohydrate
Heavy chains
CH3
VL
CL
S
S
S
S
CHO CHO
CH 2
COO— COO—
CH 3
CH 2
CH 3
VH
CH 1 C H
1V H
C L
V L
S
S
S
SS S
S S
S S
S SCOO— COO —
NH 3+
NH 3+ NH
3 +
NH3 +
S S
S S
S S
S SS
S
S
S
S S
S S
CH2
Figure 3–2. Structure of an immunoglobulin (Ig) G molecule.
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2. Serum IgA is primarily a monomer, but secretory IgA that is found in externalsecretions (eg, saliva and colostrum) is dimeric and contains a J chain polypep-tide. a. Dimeric IgA is synthesized in the intestinal submucosa and efficiently
translocated across the mucosal epithelium.
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Table 3–2. Properties of human immunoglobulin isotypes.
Property IgG IgM IgA IgE IgD
Subclasses IgG1–4 None IgA1–2 None None
Heavy chain γ µ α ε δ
CH domains 3 4 3 4 3
L chain κ or λ κ or λ κ or λ κ or λ κ or λ
Molecular massa 150,000 900,000 150,000 190,000 170,000(secreted form) 570,000b
Serum concentration 1350 150 300 0.05 3(mg/dL)
Serum half-life (days) 23 5 6 2 3
Activates complement + ++ − − −(classical pathway)
Placental transport + − − − −
Mucosal epithelial − + ++ − −transport
Mast cell degranulation − − − + −
Binding to phagocyte + −c − − −Fc receptors
Binding to Fc receptors + − − − −on natural killer cells
Antigen receptor of − + − − +naive B cells
aRefers to the predominant forms in serum and external secretions, not the form found on B cell sur-faces. bSecretory IgA found in external secretions is a dimer with an associated J chain and secretory com-ponent.cRecent evidence suggests Fcµ receptors on neutrophils may mediate host defense against spiro-chetes.
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b. During the process of translocation, epithelial cells add a 70-kDa peptide,called a secretory component (SC), to the IgA molecule (Figure 3–3).(1) SC protects secretory IgA from proteolytic digestion.(2) SC promotes the binding of secretory IgA to the mucous layer of the ep-
ithelium. F. Amino acid sequencing of myeloma H and L chains shows that they have constant
(C) and variable (V) regions.1. The amino-terminal half of an L chain is designated the variable light (VL)
domain. a. Amino acid sequence diversity in VL domains is greatest within the three hy-
pervariable regions, HV1, HV2, and HV3. b. HV regions are also called complementarity determining regions (CDR),
because they comprise the walls of the antigen-binding cleft. 2. The carboxyl-terminal half of an L chain is relatively constant and is designated
as the constant light (CL) domain (Cκ or Cλ). 3. As with VL domains, the amino-terminal VH domains of H chains are highly
variable when several H chains are compared. a. VH domains contain three hypervariable regions.b. VH domains that have different amino acid sequences generally have differ-
ent specificities. 4. The antigen-binding activity of an Ig depends on both its VH and VL domains. 5. The three carboxyl-terminal CH domains of IgG H chains are designated CH1,
CH2, and CH3. G. Structure and function in Igs are related.
1. The distribution of Ig function within Ig domains was first revealed by study-ing proteolytic fragments of the molecules.
Chapter 3: Antigens and Antibodies 33
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Pentameric IgM Dimeric IgA Secretory IgA
Disulfidebond
J chainJ chain
Hingeregion
J chain
Secretorycomponent
VH
C µ1
C µ2
C µ3
VL
CL
Cµ4
VH VL
Cα 1
Cα 2
Cα3
CL
Figure 3–3. Polymeric immunoglobulins (Ig).
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2. Enzymatic digestion of rabbit IgG antibodies with the protease papain yieldsthree fragments. a. Two are identical antigen-binding fragments (Fab) consisting of the VH +
CH1 domains. b. Each Fab can bind one molecule of antigen.c. One Fc fragment is also generated and consists of the carboxyl-terminal half
of the two disulfide-linked H chains (ie, the CH2 + CH3 domains in IgG).d. The Fc region mediates the opsonic activity of IgG antibodies by binding
them to Fc receptors on phagocytic cells. 3. The effector functions of antibodies depend on the structures of their CH do-
mains. a. Many functions of antibodies are not expressed until they have bound their
antigens, which induces conformational changes in the CH domains. b. Transplacental transport, transepithelial transport, and mast cell binding of
Igs do not require prior binding of the Ig to its antigen. c. A hinge region in many CH domains is responsible for the flexibility in an-
tibody conformation necessary for cooperative antigen binding.4. The principal functions of IgG antibodies are to serve as opsonins, activate the
complement system, provide fetal protection following transplacental trans-port, and inhibit B cell activation (Table 3–2).
5. The principal functions of IgM antibodies are to serve as antigen receptors onnaive B cells, activate the complement system, clear circulating antigen, andprovide host defense at mucosal surfaces.
6. The principal function of IgA antibodies is to provide antibody defense at mu-cosal surfaces.
7. The principal function of IgE antibodies is to mediate allergic reactions by pro-moting mast cell degranulation.
8. The principal function of IgD antibodies is to serve as an antigen receptor onnaive B cells.
ISOTYPE SWITCHING AND CONJUGATE VACCINES
• Antibody production undergoes isotype switching late in the primary adaptive immune response(Chapter 2).
• This associates new antibody functions with the same antibody specificity, a principle illustrated by theHaemophilus influenzae type b (Hib) conjugate vaccine.
• Hib is one of the leading causes of bacterial nasopharyngeal infections in children and can progress topneumonia and life-treatening meningitis.
• Immune elimination of H influenzae requires antibodies to the polysaccharide capsule of this organism.
• H influenzae capsular polysaccharide vaccines have not proven effective at eliciting opsonic IgG anti-bodies in children.
• By contrast, the conjugate vaccine consisting of Hib capsular polysaccharides covalently linked to aforeign carrier protein (eg, the tetanus toxoid vaccine protein) is quite effective at inducing protectiveIgG antibodies in children.
• A description of the Hib conjugate vaccine and other recommended pediatric vaccines can be found atwww.cdc.gov/nip/recs/child-schedule.pdf.
H. Natural antibodies appear early in life.1. Most natural antibodies belong to the IgM class of Igs.
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CLINICALCORRELATION
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2. Many natural antibodies are produced in response to carbohydrate antigenspresent on microbial flora.
3. Some natural antibodies also cross-react with carbohydrate structures on hostcells.a. The isohemagglutinins, natural antibodies to the ABO blood group anti-
gens, can mediate the destruction of transfused mismatched blood. b. Isohemagglutinins recognize the terminal sugar groups of the ABO polysac-
charide antigens expressed by erythrocytes and endothelial cells (Figure3–4).(1) Three blood group antigens are defined by this sytem: A, B, and H.(2) Because the ABO genes are expressed in a codominant fashion, the po-
tential ABO types are A, B, AB, and O.(3) Individuals produce isohemagglutinins specific for the ABO antigens
that they lack (Table 3–3).(4) With regard to blood transfusions, the universal donor is type O, be-
cause this individual lacks antigens that would be recognized by ABO-incompatible recipients.
(5) The universal recipient is type AB, because this individual lacks anti-bodies that would destroy ABO-incompatible donor erythrocytes.
c. Natural antibodies can also mediate the rejection of xenotransplants, or-gans exchanged between species (Chapter 17).
III. Additional Ig heterogeneityA. Slight sequence variations can exist between immunoglobulin molecules of the
same isotype (eg, IgG1) from different individuals.1. These inherited genetic markers reside within the CH or CL domains of human
Igs and are called allotypes. 2. Antiallotype antibodies are sometimes produced following pregnancy, blood
transfusions, or γ-globulin therapy.
Chapter 3: Antigens and Antibodies 35
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H or O A
Glu Gal Fuc GalNAc
Ceramide
B
Ceramide Ceramide
Figure 3–4. Structures of the ABO blood group antigens.
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B. Igs of the same isotype can also be distinguished from one another by their V re-gions.1. An antibody of a given specificity has unique VL + VH domains, the combina-
tion of which specifies its idiotype. 2. An antibody molecule and the B cell receptor of the clone of B cells that pro-
duced it have the same idiotype (Chapter 2). 3. Antiidiotype antibodies can block the binding of antigen to its antibody.
IV. Monoclonal IgsA. Monoclonal antibodies are only rarely produced in response to active immuniza-
tion with natural antigens.B. In abnormal conditions called monoclonal gammopathies a single clone of B
cells or plasma cells produces a monoclonal Ig.1. Malignant monoclonal gammopathies include multiple myeloma, non-
Hodgkin’s lymphoma, and Waldenström’s macroglobulinemia.2. Benign monoclonal gammopathies include light chain disease and mono-
clonal gammopathy of undetermined significance (MGUS), a conditionthat is common in the elderly.
3. Bence–Jones proteins are monoclonal Ig L chains that are found in the urine.a. The exclusion properties of the renal glomeruli permit passage of L chains,
but not H chains.b. These Bence–Jones proteins can accumulate in renal tubular epithelial cells,
where they can cause necrosis.
ABNORMAL IG SYNTHESIS AND CRYOPATHIES
• The excess production of Ig L chains can result in a number of systemic effects, including cryoglobu-linemia, the microprecipitation of circulating proteins in the cold.
• Complications of cryoglobulinemia involving Ig proteins include cyanosis of the digits, hemorrhage,thrombosis, and gangrene.
• In B cell malignancies, cryoglobulins are monoclonal and can include intact M components or free Lchains.
• In addition to treatment of the primary disease (eg, myeloma), plasma exchange and cryophoresis(reinfusion of autologous plasma following removal of the cryoglobulins) have met with some suc-cess.
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Table 3–3. Antigens and antibodies of the ABO blood group system.
Blood Group Type Genotypes Antigens Isohemagglutinins
A AA, AO A Anti-B
B BB, BO B Anti-A
AB AB A and B None
O OO H Anti-A and anti-B
CLINICALCORRELATION
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C. Hybridoma antibody technology allows production of a monoclonal antibodywith a desired specificity. 1. Hybridomas are produced by fusing a nonsecreting myeloma cell with B cells
from an animal that has been immunized with an antigen of interest. 2. Monoclonal antibody-producing hybridomas with the desired specificity are
then identified, selected, and expanded in cell culture. 3. Hybridoma antibodies show less cross-reactivity than conventional antisera and
are preferred for diagnostic tests (Chapter 5).
NOVEL ANTIBODY-MEDIATED THERAPIES
• Immunotoxins are conjugates composed of lethal plant or microbial toxins covalently linked to anti-bodies that target the conjugate to specific cells or tissues (eg, leukemia cells).
• Bispecific antibodies are genetically engineered to contain Fab regions specific for two different anti-gens (eg, CD3 on T cells and a tumor target antigen).
• Humanized mouse hybridoma antibodies are genetically engineered to contain mouse Ig hyper-variable regions embedded in a human IgG antibody framework.
• This minimizes the likelihood that the host will mount an immune response to the foreign mouse hy-bridoma antibody sequences.
• Fusion proteins produced by covalently linking cytokine receptor domains to Ig molecules have ex-tended half-lives in circulation and have proven effective for the treatment of cytokine-mediated in-flammatory diseases.
CLINICAL PROBLEMSYou are considering treatment options for a 1-year-old child with a congenital immunedeficiency. He has very low serum IgG levels and recurrent bacterial infections, and helacks B cells in his peripheral lymph nodes. You decide to treat with IVIGs, which you re-alize may be required throughout his life.
1. How often will you have to administer IVIG to maintain a consistent level of protec-tive immunity in this child?
A. Twice per week
B. Once per week
C. Once every 3 weeks
D. Once every 6 months
E. Yearly
A child is immunized by the intramuscular route at 2, 4, and 6 months of age with tetanustoxoid, a protein antigen. One week following each immunization her serum is collectedand analyzed for antitoxoid antibodies.
2. Which of the following properties would characterize the serum collected after thethird immunization compared to that collected after the first immunization?
Chapter 3: Antigens and Antibodies 37
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CLINICALCORRELATION
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A. Increased specificity for tetanus toxoid
B. Increased ability of the serum to promote the uptake of the toxoid by phagocyticcells
C. Increased complement activation by antigen–antibody complexes formed withthe serum
D. Increased reactivity with autoantigens of the host
E. Decreased binding of the toxoid
An 80-year-old man presents with slight pain on urination, and his physician orders a testfor protein in his urine. An elevated urinary protein level prompts the physician to requesta urine protein electrophoresis, which shows a protein spike.
3. Which of the following additional findings would be most consistent with a diagnosisof a benign monoclonal gammopathy?
A. A high concentration of serum IgG and elevated β and γ region proteins on pro-tein electrophoresis
B. Elevated concentrations of κ and λ L chains in his serum
C. A high κ:λ ratio (100:1) among his urinary L chains
D. An elevated erythrocyte sedimentation rate
E. Recurrent bacterial infections
Johnny is a 3-month-old infant in need of a blood transfusion. The blood bank has deter-mined that Johnny’s parents are both blood group type AB.
4. Which of the following findings would indicate that Johnny has an ABO type differentfrom that of his parents?
A. His serum reacts with type O erythrocytes.
B. His cells react with anti-A.
C. His cells react with both anti-A and anti-B.
D. His serum reacts with his father’s cells.
E. His cells react with his mother’s serum.
A researcher has produced an idiotype-specific antibody by immunizing a rabbit with anM protein purified from the serum of a myeloma patient. This antibody does not reactwith any other M protein tested.
5. With which of the following structures would this antibody react?
A. Fab fragment
B. J chain
C. CH1 domain
D. Fc fragment
E. Fc receptor binding site
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ANSWERS
1. The correct answer is C. IVIG is a γ-globulin preparation derived from pooled immunedonor plasma and contains primarily IgG, which is what this patient lacks. The half-life of human IgG in the circulation is 23 days (approximately 3 weeks).
2. The correct answer is B. One of the principal reasons for repeated immunizations is toinduce Ig class switching (eg, a change from predominantly IgM to predominantly IgGproduction). This has the effect of introducing new functions associated with the addi-tional isotypes. For example, IgG (but not IgM) is a potent opsonin due to the pres-ence of Fc receptors on phagocytic cells that recognize γ heavy chains.
3. The correct answer is C. To diagnose a monoclonal gammopathy the clinical labora-tory must demonstrate a predominance of one L chain (κ or λ) over the other, whichwould alter the normal 60:40 ratio. Monoclonal gammopathies appear on elec-trophoresis as a “spike,” whereas polyclonal gammopathies appear as an elevatedamount of protein across a wide electrophoretic range (ie, the entire γ region). Mono-clonal gammopathy of undetermined significance is a common finding in patients inthis particular age group.
4. The correct answer is D. Johnny could theoretically be either A, B, or AB. If his serumreacts with his father’s cells, he must have either anti-A or anti-B in his serum. Eitherfinding would indicate he has a blood type that is different from his parents, becauseAB individuals have no antibodies to ABO antigens.
5. The correct answer is A. If this antibody is indeed specific for only this patient’s M pro-tein, it must be recognizing the V region of the Ig. The only structure listed that con-tains V region domains is the Fab fragment.
Chapter 3: Antigens and Antibodies 39
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I. A fundamental problem posed by the unusual structure of immunoglob-ulin (Ig) molecules is solved by a novel genetic mechanism.A. Igs are unusual in that millions of different V region sequences exist among the
pool of Ig polypeptide chains.B. These diverse V regions are found within polypeptides that show limited diversity
in their C region sequences.C. The germ line genome of a species is not large enough to encode all of the poten-
tial Ig V region sequences.D. To form the pool of Ig V region sequences a limited number of inherited Ig gene
segments undergoes genetic recombination and random reassortment.1. The genetic capacity to generate the diverse family of Ig proteins exists within
the germ line of every cell.2. Rearrangements of Ig DNA by somatic recombination occurs only in B cells
and is a random pretranscriptional process.3. Diversity is generated prior to exposure to foreign antigen.4. Each member of the species has a similar potential repertoire of Igs.
II. Ig genes are initially organized in a germ line configuration.A. There are three gene families (also referred to as loci) that encode Ig polypep-
tides, the κ, λ, and H chain gene families.1. There are only 10–100 gene segments at each locus.2. Both the κ and λ chain loci contain constant (C), variable (V), and joiner (J)
gene segments (Figure 4–1).3. The H chain locus has a similar arrangement with a 5′ cluster of VH gene seg-
ments, several JH segments, a group of diversity (DH) segments (not seen inthe L chain loci), and nine CH segments.a. The CH gene segments correspond to the nine classes and subclasses of
human H chains.b. Each of the CH segments consists of a cluster of three or four exons encod-
ing the different CH domains of secreted Ig H chains (Figure 3–2). c. One or two short exons follow these CH exon clusters that code the trans-
membrane and cytoplasmic regions of membrane H chains. 4. Latent promoters are found upstream of each Vκ, Vλ, and VH segment.
NC H A P T E R 4C H A P T E R 4
IMMUNOGLOBULINGENE EXPRESSION
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Ig LOCUS DELETIONS
• Deletion mutations affecting large regions of the human Ig loci are known to exist.
• Among a consanguineous population of Tunisians, several individuals with homozygous deletions inthe H chain locus have been identified.
• One haplotype has a multigene deletion of the entire Cγ1-to-Cε segment (Figure 4–1).
• An affected individual showed normal numbers of B cells in his peripheral lymphoid tissues, but hisserum contained no detectable IgG1, IgG2, IgG4, or IgA1.
• In some instances of Ig locus deletions one Ig class can apparently compensate for the absence of an-other, thus preventing any increased susceptibility to infection.
III. The recombination of Ig gene segments precedes the expression of acomplete Ig gene. A. Somatic recombination rearranges the order of the various segments within the L
chain loci to create a functional Ig gene. B. Recombination generates diversity within the V regions of L chain polypeptides.
1. For example, recombination at the κ locus brings one Vκ segment, one Jκ seg-ment, and one Cκ segment into proximity with one another (Figure 4–2).
2. Recombination involves the cleavage of double-stranded DNA and its religa-tion.
3. A V(D)J recombinase catalyzes cleavage and is expressed only in lymphocytes.a. V(D)J recombinase consists of two components encoded by recombination
activating gene 1 (Rag1) and recombination activating gene 2 (Rag2). b. Mutations within Rag1 or Rag2 prevent the rearrangement of the Ig and T
cell receptor (TCR) loci.
Chapter 4: Immunoglobulin Gene Expression 41
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CLINICALCORRELATION
Vλ2 Vλ1Jλ2 Jλ4 Jλ3 Jλ1
DH1 DH13
Cλ2 Cλ4
Cκ
Cµ Cδ Cγ3 Cγ1 Cγ2b Cγ2a Cε Cα
Cλ3 Cλ1L L
λ-chain DNA
5' 3'
Vκ1 Vκ2 VκnL L L
κ-chain DNAn= ~85
5'
Heavy chain DNAn= ~134
3'
3'
ψ70kb
1.2kb
2.0kb
1.3kb
23kb
6.5kb
4.5kb
55kb
34kb
21kb
15kb
14kb
12kb
2.5kb
19kb
1.4kb
1.7kb
1.3kb
Jκ
JH1 JH4
ψ
VH1 VHnL L5'
Figure 4–1. Germ line configuration of the three Ig gene families.
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RAG DEFICIENCY
• Mutations in the Rag1 or Rag2 genes dramatically alter lymphocyte differentiation and cause severecombined immune deficiency (SCID).
• SCID is characterized by T−B−NK+ lymphopenia, because neither immature B cells nor thymocytes sur-vive differentiation if they cannot successfully express their antigen receptor genes.
• SCID is a pediatric emergency due to the rapid onset of fatal opportunistic infections by intracellularpathogens (primarily viral and fungal) early in postnatal life.
• Hematopoietic stem cell transplantation in the early neonatal period is a highly successful treatmentfor SCID.
4. Sequences within the noncoding introns, called recombination signal se-quences, determine which gene segments can be juxtaposed by recombination.
5. Additional enzymes catalyze the repair of these double-stranded DNA breaks. 6. The joining of a V segment to a J segment (V–J joining) results in the looping
out and loss of intervening V and J segments.7. Any J segments not joined to the V segment as well as intervening introns are
excised at the RNA processing stage. 8. The same processes occur at the λ locus.
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5'
5'
Vκ1 Jκ CκL Vκ23L VκnLGerm-lineκ-chain DNA
Rearranged κ-chain DNA
Primary RNA transcription
V-J joining
Transcription
5' 3'
Vκ1 Jκ Jκ CκL VκL3'
mRNA
Nascent polypeptide
Jκ Jκ CκVκL
3'
(A)nJκ CκVκL
Jκ Cκ
κ light chain
VκL
Jκ
Vκ
CκVκ
Cκ
ψψψ
Polyadenylation and RNA splicing
Poly-A tail
Translation
Figure 4–2. Somatic recombination and rearrangement of the κ locus.
CLINICALCORRELATION
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C. Recombination at the κ and λ loci occurs primarily in the bone marrow indepen-dent of any exposure to foreign antigen.
D. Once rearranged, the κ locus can be transcribed into a primary RNA transcript(Figure 4–2).1. Rearrangement permits the expression of the κ locus by positioning promoters
and enhancers close to one another and the transcriptional start site. 2. Transcription ends at a stop codon that follows the rearranged Cκ segment.3. Intervening RNA and nonjoined Jκ segments are removed by processing the
primary RNA transcript.4. A messenger RNA (mRNA) is produced by splicing and is then polyadenylated
and translated into a κ chain polypeptide. E. The same process permits the expression of a rearranged λ locus.
CHROMOSOMAL TRANSLOCATIONS TO IG LOCI
• Many malignant lymphoid cells, including Burkitt s lymphoma and multiple myeloma, show chromo-somal translocations that involve the Ig loci.
• The high level of genetic recombination that occurs at Ig loci during lymphocyte development makesthem particularly susceptible to these genetic abnormalities.
• Particularly frequent are translocations that include oncogenes, such as c-myc.
• Translocating genes for growth factors, various growth factor receptors, antiapoptosis genes (eg, bcl-2), and transcription factors to the transcriptionally active Ig loci can promote uncontrolled cellproliferation.
F. The process of gene rearrangement at the H chain locus is slightly different (Fig-ure 4–3).1. The first rearrangement involves the joining of a D segment with a J segment
(D–J joining).2. Following D–J joining, the V region is joined to the D–J segment by a second
recombination. 3. Intervening D, J, and V regions are deleted during these recombinations.4. H locus rearrangement occurs only in pre-B cells (Chapter 9).5. Transcription yields a primary RNA transcript consisting of joined
VHDHJHCµCδ segments. a. Transcription is initiated by promoters upstream of the joined VH segment.b. The first downstream stop codon for transcription is found downstream of
the Cδ segment.(1) There is no stop codon following the Cµ segment.(2) Primary transcripts from the rearranged H locus have the capacity to en-
code complete µ and δ polypeptide chains. (3) The same VHDHJH-encoding region is shared by the µ and δ mRNA (see
below). 6. A primary RNA transcript is synthesized, processed, polyadenylated, and
translated into an Ig H chain. 7. Assembly of H and L polypeptide chains occurs in the rough endoplasmic
reticulum.8. Glycosylation and packaging for secretion occur within the Golgi.
G. The random process of recombination that occurs within each B cell adds to thediversity of the entire B cell pool.
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H. A relatively small pool consisting of several hundred V, D, and J segments recom-bines to generate a very large potential pool (> 1010) of V region-encoding genes(Table 4–1).
I. Allelic exclusion ensures that a single B cell expresses no more than one BCR.1. Diploid species have an opportunity to express both alleles at a given locus.2. Successful rearrangements at one allele signal inhibition of rearrangements at
the homologous allele.a. If rearrangement at the first H-chain locus is nonproductive, rearrangement
is attempted at the second H locus.b. If the first allele rearranges successfully, rearrangement at the second allele is
inhibited.c. If both alleles fail to productively rearrange, the cell may undergo apoptosis.
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or
1 7 13 Cµ Cδ Cγ3 Cγ1 Cγ2b Cγ2a Cε Cα3'
JHVH1L5'
VHnL
VH1L
5'
VH21L
VH1L
5'
VH20L
VHnL
Germ-lineH-chain DNA
RearrangedH-chain DNA
Primary RNA transcript
Translation Translation
µ heavy chain δ heavy chain
mRNA
Nascent polypeptide
DH
DH1 DH6 Cµ Cδ Cγ3 Cγ1 Cγ2b Cγ2a Cε Cα3'
JH
D Cµ Cδ Cγ3 Cγ1 Cγ2b Cγ2a Cε Cα3'
Cµ Cδ3'
JHJ
JH
5'
VL
D
Cµ
or
JVL
DJVL CδDJVL
Cµ
or
DJVL CδDJVL
CµDJV CδDJV
D-J joining
Transcription
V-D-J joining
Polyadenylation, RNA splicing
(A)n (A)n
Figure 4–3. Ig H locus rearrangements.
6193ch04.qxd_mg 2/6/06 12:41 PM Page 44
d. Successful rearrangement of either κ allele inhibits rearrangements at bothof the λ loci.
e. Failing to rearrange both κ alleles signals rearrangement at the λ locus.
IV. Antibody diversity has a genetic basis. A. The immune repertoire of an individual is the sum of his or her Ig and TCR V
regions.B. Several mechanisms contribute to the generation of the potential Ig repertoire
(Table 4–1).1. Hundreds of V, D, and J segments are present in the germ line that can com-
bine to code for Ig V regions.2. Combinatorial association of these segments in a random fashion adds diver-
sity.3. Imprecise joining (joining flexibility) can generate several sequence varia-
tions spanning the recombined region.4. Nucleotide addition or deletion can occur at joining sites during recombina-
tion. a. Nucleotides are added by the enzyme terminal deoxynucleotidyltrans-
ferase (TdT) to generate junctional diversity.
Chapter 4: Immunoglobulin Gene Expression 45
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Table 4–1. Various mechanisms contribute to the diversity in Ig molecules.
Mechanism κ λ H
A pool of V, D, 40 V segments 30 V segments 50 V segmentsand J segments 5 J segments 4 J segments 27 D segments
6 J segments
Combinations of VDJ joining 40 × 5 = 200 30 × 4 = 120 51 × 27 × 6 = 8262
Imprecise joining Significant Significant Significant amplification amplification amplification
Nucleotide addition Significant Significant Significant or deletion amplification amplification amplification
Combinations of (200 + 120) × 8262 = 2.64 × 106
H + L polypeptidesa
BCR editingb + + +
Somatic + + +hypermutationb
aThis estimate of the potential Ig repertoire does not include the amplification derived from imprecisejoining and nucleotide additions or deletions. bThe effects of these processes are difficult to estimate, can depend upon exposure to antigen, and af-fect both L and H chain gene expression (Chapter 9). BCR, B cell receptor.
6193ch04.qxd_mg 2/6/06 12:41 PM Page 45
b. Because the HV3 region of Ig polypeptides is encoded by the sites of V(D)Jjoining, junctional diversity is greatest within this hypervariable region (Fig-ure 4–3).
5. Combinatorial pairing of H and L polypeptide chains further expands the po-tential repertoire of Ig molecules.
6. Somatic hypermutation of V region sequences and BCR editing (Chapter 9)add to the diversity of mature B cell specificities.
C. The utilized repertoire of an individual can be different from the potential reper-toire of the species.1. Many recombinations are nonproductive and signal either cell death or a sec-
ond recombination event.2. Some V regions show specificity for self antigens resulting in the deletion of the
clone expressing those antigen receptors.3. Some H and L polypeptide chains do not pair to form functional antigen re-
ceptors.4. At any one time the host may not possess sufficient numbers of B cells to ac-
commodate expression of all potential BCR of the species. 5. Any expansion in a clone of effector or memory B cells can reduce the size of
the available repertoire by limiting the space for newly emerging naive B cellswith novel specificities.
6. The generation of memory B cells can increase the repertoire by signaling so-matic hypermutation of V regions (Chapter 9).
V. A single B cell can express BCRs of different Ig classes.A. A mature naive B cell in the periphery expresses both µ- and δ-containing mem-
brane BCRs. 1. The primary RNA transcribed from a rearranged H locus gene contains exons
for both µ and δ constant regions (Figure 4–4).a. Differential processing of the RNA produces mRNAs that code for either µ
or δ H chains. b. The VDJ sequences of the two mRNA species are the same.
2. These two BCRs differ from one another only in their CH domains.a. The V regions and L chains of the two BCRs are identical.b. The idiotypes and specificities of the two BCRs are identical.
3. At different stages in the differentiation of B cells (Chapter 9), RNA processingand translation determine whether membrane IgM, membrane IgD, or bothare expressed by the cell.
BICLONAL MYELOMA
• Very rarely patients with multiple myeloma will synthesize two different M components in theirplasma.
• These monoclonal Igs belong to different Ig classes (eg, IgM and IgG) but typically have identical V re-gion sequences.
• Antiidiotype antibodies specific for the combining site of one M protein react with the combining site ofthe second M protein.
• The disease process of myeloma is thought to begin at the pre-B or immature B cell stage, at whichtime V(D)J sequences are being established by recombination.
• Commitment to the H chain class occurs later, during which these rare multiple isotypic neoplasias arise.
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B. Normal B cells maintain their specificity as they undergo Ig class switchingfollowing antigen stimulation.1. Class ( or isotype) switching refers to a change from the expression of IgM
and IgD to the expression of one of the other isotypes (ie, IgG).a. Class switching involves a change in the CH region of the heavy polypeptide
chain of the Ig molecule.b. During class switching, the L chain remains the same.c. The VH and VL regions of the Ig, which determine specificity, remain the
same during class switching.
Chapter 4: Immunoglobulin Gene Expression 47
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A
S Sδ1 δ2 δ3M2M1 M2M1J JDVL5' 3'
µ1 µ2 µ3 µ4
Cµ
δ1 δ2 δ3 21JDVL
Cδ
δ1 δ2 δ3(A)n
M2M1J JDVL5'
Cδ
~6.5 kb
~6.5 kb
Poly-A site 1 Poly-A site 2 Poly-A site 3 Poly-A site 4
Splicing
δm transcript
Translation
(A)n
Membrane IgD
M
B
S Sδ1 δ2 δ3M2M1 M2M1J JDVL5' 3'
µ1 µ2 µ3 µ4
Cµ
S(A)n
M2M1JDVL5'
5'
µ1 µ2 µ3 µ4
Cµ
µ1 µ2 µ3 µ4JDVL
Cδ
Poly-A site 1 Poly-A site 2 Poly-A site 3 Poly-A site 4
Splicing
µm transcript
Translation
µm mRNA
5'δmmRNA
Membrane IgM
(A)n21
M
J
Figure 4–4. B cell receptors (BCRs) containing µ and/or δ heavy chains.
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2. At the DNA level, Ig class switching involves a change in the order of the CHsegments (Figure 4–5).a. DNA between the rearranged VDJ segment and the new CH segment is
looped out by recombination.b. Class switching is irreversible, because the intervening DNA is excised and
discarded. c. Isotype switching always involves a new downstream (3′) CH gene segment. d. A switch from IgM and IgD to IgG expression, for example, can be followed
by a second switch to another isotype (eg, IgE). C. Membrane Ig H chains differ from the secreted form of the same polypeptide only
in the presence of membrane-spanning domains at their carboxy-termini (Figure4–4). 1. A single primary RNA transcript is differentially processed to yield two differ-
ent mRNAs that encode for either membrane or secreted heavy chains.2. All of the Ig isotypes have membrane and secreted forms. 3. The membrane antigen receptor (BCR) and secreted antibody molecules of a
clone of B cells have the same idiotype and specificity.
VI. Defining the genetic basis for Ig diversity and expression explains muchof the unique behavior of B cells (Table 4–2).A. B cells express antigen receptors that are membrane-bound forms of secreted anti-
body molecules.B. Allelic exclusion ensures that the BCR expressed by a B cell is monospecific.
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Cµ Cγ3Sµ Cδ3'
JDVL5'
Sγ3 Cγ1Sγ1 Cγ2bSγ2b Cγ2aSγ2a CεSε CαSα
5' 3'
Cγ1 Cγ2bSγ2b Cγ2aSγ2a CεSε CαSα
Cµ
Cγ3
Cγ3
Sµ
Cδ
Cδ
5'JDVL
5'SµJDVL 3'Sγ1
3'Sµ
5'Sγ1
Sγ3
Sγ3
Sγ1
3'
Cγ1 Cγ2bSγ2b Cγ2aSγ2a CεSε CαSα
Cµ
DNA looping
Recombination at Sµ and Sγ1
+
Figure 4–5. Genetic basis for Ig class switching.
6193ch04.qxd_mg 2/6/06 12:41 PM Page 48
C. The antigenic specificity of a B cell is maintained throughout its life span despiteclonal expansion, memory cell production, antibody secretion, and isotype switch-ing.
D. T cells utilize many of the same mechanisms to express an even more diverse set ofantigen receptors.
CLINICAL PROBLEMSMary is a 3-year-old patient who presents with a fever, labored breathing, and shortness ofbreath. Her history includes recurrent bacterial infections (sinusitis and otitis media) since1 year of age. She has been prescribed oral antibiotics as often as six times per year. Aftereach course of treatment, the infections subside, but a recurrence of symptoms often fol-lows within several weeks. Laboratory tests indicate a mild neutropenia, but no otherhematological abnormalities. Her serum IgG and IgA levels are far below those of age-matched controls, whereas her serum IgM levels are significantly elevated. When immu-nized with tetanus toxoid, a vaccine she has received before, she makes no detectable IgGantibody response.
Chapter 4: Immunoglobulin Gene Expression 49
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Table 4–2. Molecular correlates of the clonal selection theory.
Prediction Molecular Explanation
Lymphocytes are precommitted in Gene rearrangement occurs in each their antigen specificity. lymphocyte during its differentiation in the
bone marrow and thymus.
A single cell expresses receptors Rearrangements that lead to BCRa or with a uniform antigen specificity. TCRa expression are followed by the
inhibition of further Ig or TCR locus rearrangements (allelic exclusion).
All antigen receptors on a cell Each antigen receptor variant on a cell are uniform and identical. uses the same rearranged V region
segments.
Daughter cells retain the antigen Once expressed, V region genes are specificity of the parental cell. relatively stable in lymphocytes.
The antigen receptor of a cell has a The same V regions are used to encode specificity identical to the antibody for membrane and secreted Ig molecules.the cell produces.
aBCR, B cell receptor; TCR, T cell receptor.
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1. Which of the following is the most likely cellular or molecular defect in this patient?
A. Failure of her B cells to undergo Ig class switching
B. A block in all B cell differentiation
C. Rag1 deficiency
D. Toll-like receptor deficiency
E. DiGeorge syndrome
A 2-year-old patient presents with a history of infections that suggests an immune defect,and the clinical laboratory reports serum IgG levels one-third that of age-matched con-trols. The child is ABO blood type A.
2. Which of the following findings would be more consistent with a diagnosis of H locusdeletion affecting only Cγ segments than a complete absence of B cells?
A. Decreased IgM levels in her serum
B. The absence of follicles in her splenic white pulp
C. The absence of Ig in her saliva
D. The presence of B cells in the follicles of her lymph nodes
E. The lack of isohemagglutinins in her serum
You have isolated a population of plasma cells from a patient who was recently immunizedwith a protein vaccine. Her cells secrete IgG in vitro, but lack any membrane IgG.
3. Which of the following accounts for this finding?
A. DNA rearrangement following antigen stimulation deletes BCR-encoding genesegments.
B. The Ig H chain locus does not code for a membrane form of γ chains.
C. Differential RNA processing favors the synthesis of a secreted form of γ heavychains.
D. Plasma cells that secrete IgG express IgA on their surface.
E. Only surface L chains are expressed by B cells.
You have a patient with an IgG1κ myeloma. Analysis of DNA from the myeloma cells in-dicates that the H and κ alleles that he inherited from his father (paternal) have been re-arranged.
4. Which of the following loci could still be in the germ line configuration in these cells?
A. Maternal κ allele
B. Maternal λ allele
C. Paternal λ allele
D. Maternal H allele
E. All of the above loci could be in the germ line configuration.
You have a patient with multiple myeloma and examine a preparation of cellular mRNAfrom the myeloma cells by Northern blotting. The probe you use detects a VHDHJH se-quence that is unique to this particular myeloma cell. The results of this experiment indi-
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cate that the myeloma cells have four mRNA species of different sizes, each containing thetarget sequence.
5. Which one of the following lists of Ig polypeptides is probably encoded by these fourmRNAs?
A. µ, δ, γ, and α H chains
B. κ, λ, µ, and δ chains
C. Membrane µ, membrane δ, secreted µ, and secreted δ H chains
D. Secreted µ, δ, κ, and λ chains
E. Secreted µ, δ, α, and ε H chains
ANSWERS
1. The correct answer is A. Mary produces IgM, which rules out an absence of B cells or aRag deficiency. The latter would cause a complete absence of both T and B cells, whichwould have resulted in the onset of viral and fungal infections shortly after birth.Mary’s history of infections, serum IgG and IgA levels, and diminished antibody re-sponse suggest that she lacks the ability to class switch from IgM production to themore “mature” isotypes (IgG and IgA).
2. The correct answer is D. With γ chain gene deletions, mature B cells are still producedand can be found in the periphery. They simply fail to synthesize IgG antibodies afterantigen stimulation. With a complete absence of B cells, follicles in the lymph nodesand spleen fail to develop.
3. The correct answer is C. Whereas mature B lymphocytes express membrane BCR mol-ecules, plasma cells do not normally express membrane Ig. This decision in the B celllineage to express membrane Ig, secreted Ig, or both is made at the level of RNA pro-cessing.
4. The correct answer is E. The H locus rearranges first, followed by either the κ or λlocus. If successful rearrangements had first been undertaken at the paternal H and κalleles, then the maternal H and κ alleles would remain in the germ line arrangement.Because the κ locus was successfully rearranged in this cell, both λ alleles could havebeen suppressed and could have remained in the germ line configuration.
5. The correct answer is C. Because the probe detects only mRNAs with VDJ sequencesof H chains, light chain mRNA should not be detected. Messenger RNA for µ and δchains could be expressed by one myeloma cell by differential splicing, and thesemRNA would differ only in their CH regions. µ and δ H chains have different molecu-lar masses, and their membrane forms, which are expressed by a portion of themyeloma cells, are longer than their secreted forms.
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I. Interactions between antibodies and antigens are specific, reversible, andreach a state of equilibrium defined by the following equation:
Ab + Ag ←→ AbAg
A. The molecular forces that contribute to the strength of antibody–antigen (Ab–Ag)binding include ionic bonding, hydrophobic interactions, hydrogen bonding, andvan der Waals interactions. 1. Affinity is a measure of the strength of binding between an antibody and a
monovalent antigen. a. Antibody affinities are reflected in dissociation constants (Kd) and typically
range from 10–6 to 10–11 M. b. The average affinity of an antiserum generally increases with repeated immu-
nizations, a phenomenon referred to as affinity maturation (Chapter 9).c. As a general rule, immunoglobulin (Ig) G antibodies have higher affinities
than IgM antibodies.2. Antibody avidity refers to the aggregate strength of Ab–Ag binding when mul-
tiple antibody-combining sites of an antibody molecule interact with more thanone determinant of a multivalent antigen. a. High avidity reactions are common with natural antigens that contain multi-
ple copies of the same antigenic determinant (eg, polysaccharides). b. Because of their pentameric structure, IgM antibodies generally have a higher
avidity than IgG antibodies.B. The specificity of Ab–Ag reactions is similar to the specificity that enzymes show
for their substrates. 1. Antibodies can distinguish between sterioisomeric forms of chemical groups.2. Cross-reactivity is the tendency of an antibody to react with more than one
antigen.a. Cross-reactive antigens (eg, bovine and equine serum albumin) share the
same or similar antigenic determinants.b. In general, polyclonal antisera are more cross-reactive than monoclonal an-
tibodies.c. B cell and T cell receptors (BCR and TCR) can also show cross-reactivity
(Chapter 6).
NC H A P T E R 5C H A P T E R 5
ANTIGEN RECOGNITION BY ANTIBODY
52
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CROSS-REACTIVITY AND CROSS-PROTECTION
• Immunity induced by vaccination, infection, or environmental exposure to antigens can lead to eitherbeneficial or deleterious immunological cross-reactions (Table 5–1).
• Edward Jenner developed an effective means of eliciting cross-protective immunity to the variola(smallpox) virus by immunizing individuals with vaccinia virus, which causes cowpox.
• The nonpathogenic mycobacterium bacille Calmette-Guérin (BCG) induces in vaccinees cross-protective immunity against the causative agent of tuberculosis, Mycobacterium tuberculosis.
• Allergic responses to cross-reactive determinants on birch pollen can lead to food allergies to apples,plums, and hazelnuts.
C. When antibodies bind to their respective antigens, neither is covalently modified,although both can undergo important conformational changes.1. Some cell surface Fc� receptors bind IgG Fc regions only after they have bound
antigen.a. These Fcγ receptors are generally of low affinity (Kd = 10–6–10–7 M) and me-
diate opsonization by phagocytic cells. b. High affinity Fcγ and Fcε receptors (Kd = 10–8–10–10 M) can bind
monomeric IgG and IgE, respectively, in the absence of antigen.c. High-affinity Fc receptors mediate placental transfer of monomeric IgG.
2. The activation of complement by IgG and IgM antibodies requires antigenbinding that reveals cryptic complement-binding sites within the CH2 domains(Chapter 8).
3. Membrane Igs that serve as antigen receptors on B cells undergo conforma-tional changes when their antigens are bound.a. This permits protein–protein interactions between the C-terminal domains
of membrane H chains and two other members of the receptor complex, Igαand Igβ.
b. BCR–Igα–Igβ interactions initiate transmembrane signaling in B cells(Chapter 9).
Chapter 5: Antigen Recognition by Antibody 53
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CLINICALCORRELATION
Table 5–1. Clinically important immunological crossreactions.
Antibody Specificity Cross-reactive Antigens Effect
Microbial carbohydrates ABO erythrocyte antigens Mediate transfusion reactions
Steptococcal M protein Cardiac antigens Rheumatic fever
Beef heart cardiolipin Human cardiolipin False positive tests for syphilis
House dust mite Shrimp Food allergies allergens
Timothy grass allergens June grass allergens Seasonal allergies
Methyldopa Rh antigens Autoimmune hemolytic anemia
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D. A complex formed between an antibody and its antigen is often referred to as animmune complex. 1. Both circulating and tissue-bound immune complexes have proinflammatory ef-
fects (Chapter 13).2. Circulating soluble immune complexes typically form in antigen excess and de-
posit in the skin, blood vessel walls, joint spaces, and basement membranes ofrenal glomeruli.
3. A number of important laboratory tests can detect immune complexes in bodyfluids or tissues and aid in diagnosing immune complex diseases (Chapters 13and 16).
II. The measurement of Ab–Ag reactions is the basis for many clinicaldiagnostic tests in immunology and microbiology (Table 5–2).A. Serology refers to techniques that measure the reactivity of serum antibodies with
their antigens.
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Table 5–2. Selected applications of immunoassays in the clinical laboratory.a
Measurement Assay Specific Examples
Ig concentration Nephelometry Serum IgG, IgM, IgA, and IgE
Monoclonal gammopathy Immunoelectrophoresis M componentImmunofixation
ComplementIndividual components ELISA C1, C2, C3, C4Total hemolytic activity Complement fixation CH50
test
Antibodies to infectious agents HIV ELISA, Western blot Anti-gp24, gp41, gp120,
gp160Streptococcus Agglutination Anticapsular polysaccharideTreponema pallidum Agglutination VDRL test for syphilis
AutoimmunityAnti-Ig antibody Passive hemagglutination Rheumatoid factor
Antinuclear antibodies Immunofluorescence ANA, anti-dsDNA
Cell surface markers Normal lymphocytes Flow cytometry CD4, CD8, CD19Tumor cells Flow cytometry CD10 on leukemia cells
aIg, immunoglobulin; ELISA, enzyme-linked immunosorbent assay; HIV, human immunodeficiencyvirus; VDRL, Venereal Disease Research Laboratory; ANA, antinuclear antibody; dsDNA, double-stranded DNA.
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B. The relative concentration of an antibody is often expressed as a titer, which is thereciprocal of the greatest dilution of the antiserum that shows a reaction with itsantigen.
C. Particulate antigens agglutinate when combined with their antibodies.1. Hemagglutination occurs when antibodies to erythrocyte surface antigens
cause aggregation of cells bearing the respective antigen.a. In blood typing, agglutinating antibodies of known specificities (eg, anti-
RhD) are used to determine the antigenic phenotypes of prospective donorsand recipients.
b. In the major cross-match, cells from the donor are mixed with serum fromthe recipient as a means of detecting preformed recipient antidonor antibod-ies.
2. The Coombs test (Chapter 16), a specialized hemagglutination test, detects an-tibodies on erythrocytes or platelets.a. In the Coombs test, the patient’s cells are mixed with the “Coombs
reagent,” which is an antihuman IgG.b. IgG antibody-coated erythrocytes or platelets agglutinate in the presence of
the Coombs reagent.c. Agglutination can indicate the presence of antibodies against haptens (eg,
drugs) bound to the cell surface or antibodies specific for endogenous ery-throcyte antigens (eg, anti-RhD).
RH DISEASE OF THE NEWBORN
• Rh incompatibility between Rh-negative mothers and their Rh-positive children can lead to the pro-duction of antibodies by the mother that cause hemolytic anemia in the fetus.
• First pregnancies are generally not affected, because the initial maternal IgM antibodies do not crossthe placenta.
• Subsequent pregnancies are at risk due to isotype switching to IgG in the mother.
• A definitive diagnosis of Rh disease in an affected newborn can be made, in part, with the Coombs test,which detects IgG on the surface of the neonate’s erythrocytes.
3. The species or strain of a bacterium can be determined by serological agglutina-tion tests. a. Serological typing provides a more rapid identification of a bacterial species
or group (eg, group A Streptococcus or Salmonella serogroups) than does cul-turing the specimen.
b. Agglutination assays can also reveal serotypes associated with specific diseases(eg, Escherichia coli serotype O157:H7 and hemorrhagic colitis).
D. Soluble antigens present at high concentrations form visible precipitates whencombined with their antibodies.1. Immunoprecipitation techniques are relatively insensitive and require micro-
gram per milliliter to milligram per milliliter concentrations of antigen. 2. Large insoluble Ab–Ag precipitates can be detected by light scatter using an in-
strument known as a nephelometer.3. The amount of immune precipitate that forms is a function of the Ab:Ag ratio
(Figure 5–1).a. At an optimum ratio, called equivalence, the maximum amount of precipi-
tate is observed and neither free Ab nor free Ag is found in solution.
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b. In the range of Ag excess, small soluble Ab1Ag2 complexes are formed.c. Large complexes are typically cleared by phagocytic cells, whereas smaller sol-
uble complexes can cause immune complex disease.4. Precipitated Ab–Ag complexes can also be visualized in agar gels.
a. In agar gel immunodiffusion, solutions of Ab and Ag diffuse toward oneanother resulting in the formation of a visible precipitate at the diffusion in-terface (Figure 5–2).(1) A pattern of identity indicates that two antigens are identical with respect
to the determinant(s) recognized by the antiserum.(2) A pattern of partial identity occurs when two antigens share some, but
not all, of their antigenic determinants.(3) A pattern of nonidentity forms when two antigens have unique determi-
nants not found in the other.b. Immunofixation, which combines the technique of electrophoresis with im-
munoprecipitation, is used to analyze antigens in complex biological samples,such as serum (Figure 5–3). (1) Test samples are first electrophoresed in an agar gel.(2) The electrophoresed proteins are then detected with specific antibodies
that precipitate the antigen.(3) These insoluble immune precipitates are stained with a protein stain.
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Ag-A
b pr
ecip
itat
eAntibody-excess
zoneEquivalence
zoneAntigen-excess
zone
Supernatants:Excess AbExcess Ag
Antigen added(constant amount of antibody)
+ + + + +— — — — —
— —
+ +— —
+ +— —
— ——
Figure 5–1. The precipitin curve. Ag, antigen; Ab, antibody.
6193ch05.qxd_mg 2/6/06 03:22 PM Page 56
POLYCLONAL AND MONOCLONAL GAMMOPATHIES
• Hypergammaglobulinemia can occur following repeated immunization, infection, or abnormal Bcell differentiation, including neoplasia.
• A polyclonal gammopathy generally signals infection, whereas a monoclonal gammopathy indi-cates a benign or malignant condition affecting a single clone of B cells.
• Benign monoclonal gammopathy of undetermined significance (MGUS) is common in the elderly,occurring at a frequency of approximately 3% in persons over 70 years of age.
• Because many monoclonal conditions are malignant, it is important to determine whether a hyper-gammaglobulinemia is monoclonal.
• Immunofixation is used to ascertain whether the elevated γ-globulins have a single H chain class and Lchain type, which means they are likely monoclonal.
Chapter 5: Antigen Recognition by Antibody 57
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CLINICALCORRELATION
Ag 1 Ag 1, 2
Ab anti-1
Ag 1 Ag 2, 3
Pattern ofnonidentity
Pattern of partialidentity
Pattern of identity
Ab anti-1Ab anti-2Ab anti-3
Ag 1 Ag 1, 2
Ab anti-1Ab anti-2
Figure 5–2. Agar gel immunodiffusion. Ag, antigen; Ab, antibody.
Anti–µ
Normal serum IgGκ myeloma serum
Anti–α Anti–κ Anti–λ Anti–µ Anti–γAnti–γ Anti–α Anti–λAnti–κ
Figure 5–3. Detection of a monoclonal gammopathy by immunofixa-tion.
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E. Sensitive immunoassays are required to detect antigens that exist at low concentra-tions (picogram per milliliter to nanogram per milliliter) in clinical samples. 1. Radioimmunoassays use radiolabeled antigens or antibodies.
a. The competitive radioimmunoassay measures the ability of a test sample (eg,patient serum) to compete with a radiolabeled antigen for binding to an im-mobilized antibody.
b. Immunoassays of this type require that dilutions of purified antigen be in-cluded as standards.
c. The radioallergosorbant test is a radioimmunoassay that measures the con-centration of serum IgE antibody to a known allergen (Chapter 13).
2. Enzyme-linked immunosorbent assays (EIA or ELISA) use enzyme-conju-gated antibodies (E-Ab) to detect antigens. a. The E-Ab–Ag complexes are detected by their ability to convert a chro-
mogenic substrate into a colored product.b. Like radioimmunoassay (RIA), the ELISA can be used to measure antigen or
antibody concentrations and shows sensitivity for antigens in solution in thepicogram per milliliter range.
c. Many home pregnancy tests use ELISA technology to detect human chori-onic gonadotropin in the urine.
3. Immunoblotting (Western blotting) uses either radiolabeled or enzyme-conju-gated antibodies to detect antigens within a complex sample, such as serum or atissue extract.a. The sample is first electrophoresed in a polyacrylamide gel under conditions
that separate antigens according to their molecular weights.b. Separated proteins are then transferred from the gel to a membrane.c. The membrane is treated with an E-Ab.d. E-Ab–Ag complexes are detected by incubating the membrane with a chro-
mogenic substrate, which forms an insoluble colored precipitate on the com-plex.
e. Western blots are often used to confirm initial screening tests, such as anELISA.
F. Immunofluorescence assays use fluorescenated antibodies to detect tissue- or cell-bound antigens. 1. Because of their specificity, the most popular antibodies for this purpose are
monoclonal antibodies.2. The availability of multiple fluorochromes (dyes) enables polychromatic analysis
of more than one antigen at a time.3. Specialized equipment (eg, a fluorescence or confocal microscope or flow cy-
tometer) is required to detect the fluorescence emitted from the stained sample.4. Tissue immunofluorescence is routinely used to enumerate certain markers in
tissue sections (eg, tumors). 5. Flow cytometry is a specialized application of immunofluorescence in which
individual cells in suspension are analyzed for the expression of a givenmarker(s)(Figure 5–4). a. The cell suspension (eg, blood) is first treated with the fluorescenated anti-
body to label the cell subset of interest.b. The labeled cell suspension is then sprayed across the path of a laser to excite
the fluorochrome.
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c. Individual cells are scored for their intensity of fluorescence emission.d. Flow cytometry is the preferred technique for enumerating CD markers on
human cells (Appendix I).e. Polychromatic flow cytometry simultaneously detects multiple markers on
a single cell (Figure 5–5).f. Individual cells expressing these markers can be physically purified by a mod-
ification of flow cytometry called fluorescence-activated cell sorting(FACS).
PHENOTYPING LYMPHOMAS AND LEUKEMIAS BY FLOW CYTOMETRY
• An important application of flow cytometry is the phenotyping of hematological malignancies usingmonoclonal antibodies to various CD markers.
• This approach can establish the number of different cell populations present in a sample, their lineage,and their stage of differentiation.
• For example, a typical B cell chronic lymphocytic leukemia (B cell-CLL) expresses membrane Ig, CD5,CD19, CD20, and CD22.
• By comparison, a plasmacytoma typically does not express membrane Ig, CD19, CD20, or CD22, butcontains intracytoplasmic Ig.
Chapter 5: Antigen Recognition by Antibody 59
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Cellsstainedwith:
Beams splitters
Red fluorescence
Green fluorescence
90° light scatter(granularity)
Foward lightscatter (size)
Laser
Anti-A
Anti-B
0.1 1 10 100 1000
Red fluorescence
0.1 1
Relative intensityRelative intensity
10 100 1000
Green fluorescence
Cell
num
ber
A+ B+
Figure 5–4. Schematic of a flow cytometer.
CLINICALCORRELATION
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CLINICAL PROBLEMSA 1-year-old child with a history of chronic sinusitis, otitis media, and pneumonia is sus-pected of having a primary immune deficiency. He has benefited from antibiotics and in-travenous immunoglobulins and shows a very low concentration of serum IgG and noIgM. Analysis of the patient’s lymph node cells by flow cytometry shows normal numbersof CD3+ lymphocytes, but an absence of cells expressing membrane IgM.
1. Which of the following diagnoses is most consistent with the data presented for this pa-tient?
A. Severe combined immune deficiency (SCID)
B. X-linked agammaglobulinemia (XLA)
C. Selective IgG deficiency
D. Light chain disease
E. B cell chronic lymphocytic leukemia
You decide to determine whether the patient in question 1 can mount a secondary anti-body response to tetanus toxoid. Ten days after immunizing with the toxoid, you measurethe titer of serum antibodies to the foreign protein.
2. Which of the following laboratory tests would be most appropriate for measuring thisresponse?
A. Flow cytometry
B. ELISA
C. Immunofluorescence
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Red
Anti
-CD
19
100 101 102 103 104
Green Anti-CD3
100
101
104
103
102
Figure 5–5. Multicolor flow cytometry analysis of human blood lymphocytes.
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D. Immunoblotting (Western blotting)
E. Immunodiffusion in gels
You have a patient with recurrent infections and decide to examine a biopsy of her lymphnode for potential structural abnormalities. Immunohistological staining reveals very fewcells in the diffuse cortex that stain with a peroxidase-conjugated antibody to CD3 fol-lowed by a chromogenic peroxidase substrate. Unstained cells are present in the superficialcortex of the lymph node.
3. Which of the following diseases is consistent with this finding?
A. Toll-like receptor deficiency
B. Severe combined immunodeficiency (SCID)
C. Chronic granulomatous disease
D. DiGeorge syndrome
E. Multiple myeloma
A 32-year-old patient presents with lymphopenia, but no other hematological abnormali-ties. He has mucocutaneous candidiasis, a yeast infection of the mucous membranes, andis seronegative for HIV-1 by ELISA.
4. Which of the following flow cytometry findings with blood lymphocytes [peripheralblood mononuclear cells (PMBCs)] would nonetheless still support a diagnosis of HIVinfection in this patient?
Chapter 5: Antigen Recognition by Antibody 61
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A B
D E
CD8
APC-
Cy7
101 102 103 104 105
CD4 FITC
102
105
104
103
101
CD8
APC-
Cy7
101
CD4 FITC
102
105
104
103
101
CD8
APC-
Cy7
101
CD4 FITC
102
105
104
103
101
C
102 103 104 105
CD8
CD4
102 103 104 105
CD4 FITC CD4 FITC
102 103 104 105
102 103 104 105
PBMCs PBMCs
PBMCs PBMCs
PBMCs
CD8
APC-
Cy7
101
102
105
104
103
101
CD8
APC-
Cy7
101
102
105
104
103
101
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A. Panel A
B. Panel B
C. Panel C
D. Panel D
E. Panel E
A patient with multiple myeloma shows proteinuria, and you wish to characterize the uri-nary protein. Using immunodiffusion, you react a rabbit antiserum specific for humanIgG with the patient’s serum and her urine.
5. Which of the patterns shown below would suggest that the urinary protein is an Ig Lchain?
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A B C D E
Serum Urine Ab
A. Pattern A
B. Pattern B
C. Pattern C
D. Pattern D
E. Pattern E
ANSWERS
1. The correct answer is B. The history and flow cytometry data are consistent with an an-tibody deficiency that results from the absence of peripheral B cells. Although SCIDwould also show aberrant B cell differentiation, T cells would be absent in this diseaseas well.
2. The correct answer is B. Among the choices, only ELISA is a quantitative assay. Im-munoblotting is not quantitative, and immunodiffusion requires high concentrationsof antibody and antigen to visualize immune precipitates.
3. The correct answer is D. DiGeorge syndrome (thymic dysplasia) results in a selectivedeficiency of T cells and an acellular appearance in T cell-dependent areas of the lymphnodes.
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4. The correct answer is D. There is a selective depletion of CD4+ T cells in patients withHIV infections. For a comparison with the normal pattern, see panel A. The pattern inpanel B is not typical for blood because it contains double-positive cells, which are nor-mally seen only in the thymus.
5. The correct answer is C. The excess urinary proteins in myeloma are generally Ig Lchains (Bence–Jones proteins), which would show a cross-reaction with the patient’sserum monoclonal Ig (M component). Because the serum Ig would contain antigenicdeterminants on their H chains not found on the urinary L chains, a pattern of partialidentity would appear.
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I. The T cell receptor (TCR) for antigen is a complex consisting of anantigen-specific heterodimer (TCR) and four additional peptides of theCD3 family (Figure 2–5).A. TCR structure is similar to that of the B cell receptor (BCR) (Table 6–1).
1. The α, β, γ, and δ polypeptides are transmembrane proteins with short cyto-plasmic domains.
2. TCR peptides have amino acid sequence homology with Ig peptides and be-long to the immunoglobulin gene superfamily.
3. Each TCR peptide has a V domain and a C domain (eg, VαCα in α chains),which are stabilized by intrachain disulfide bonds.
4. The two V domains (eg, Vα + Vβ) form a monovalent ligand-binding site muchlike an Ig Fab fragment.
5. The membrane-distal face of the TCRαβ and TCRγδ receptors that contacttheir ligands has a flat conformation, rather than the cleft seen in immunoglob-ulins (Igs) (Figure 6–1).
6. Of peripheral T cells 95% bear TCRs composed of αβ heterodimers; the re-maining T cells bear TCRs composed of γδ heterodimers.
7. CD3 �, �, �, and � polypeptide chains are transmembrane signaling compo-nents of the receptor complex.
8. The TCR is never expressed without CD3 peptides; the complete CD3 com-plex is never expressed on the cell surface without a TCR heterodimer.
CD3 DEFICIENCY
• Rare immune deficiencies affecting the expression of the TCR result from natural mutations in the CD3γ and ε chains.
• These patients present with severe lymphopenia at birth due to an inability of their thymocytes to sig-nal through an early form of the TCR called the pre-TCR, which requires CD3 for its expression.
• Without a functional pre-TCR, immature thymocytes do not develop properly and cellular immunity isimpaired (Chapter 10).
• Opportunistic viral and fungal infections occur early in life and require aggressive treatment.
B. The expression of TCR genes requires their rearrangement by recombination dur-ing cell differentiation in the thymus (Figure 6–2).
NC H A P T E R 6C H A P T E R 6
T CELL RECOGNITIONOF AND RESPONSE
TO ANTIGEN
64
CLINICALCORRELATION
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Chapter 6: T Cell Recognition of and Response to Antigen 65
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Table 6–1. Distinguishing features of the BCR and TCR.a
Feature BCR TCR
Antigen-specific component Membrane Ig αβ or γδ heterodimer
Receptor valence Bivalent Monovalent
Signaling peptides Igα, Igβ CD3 γ, δ, ε, ζ
Ligand Native epitopes of Processed peptides plus proteins, carbohydrates, MHC or glycolipids plus lipids, nucleic acids CD1
Isotype switching Yes No
aBCR, B cell receptor; TCR, T cell receptor; Ig, immunoglobulin; MHC, major histocompatibility com-plex.
TCR
Cβ
Vβ
β2m
MHC
Peptide
Cα
Vα
α2
α1
α3
Figure 6–1. Model of a typical T cell receptor (TCR) showing the structure of theligand-binding surface. MHC, major histocompatibility complex. (Adapted, with per-mission, from Garcia KC: An αβT cell receptor structure at 2.5 A and its Orientationin the TCR-MHC complex. Science 1996;274:209.)
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1. The TCR genes are found at three genetic loci, α/δ, β, and γ.2. Variable (V), joining (J), and constant (C) gene segments are found at each
locus (Table 6–2). 3. Diversity (D) segments are present within the β and δ loci.
C. The diversity of the TCR repertoire arises from genetic mechanisms that are simi-lar to those used to create a diverse set of Ig molecules.
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Table 6–2. TCR locus gene segments.a
Segment TCRα TCRβ TCRγ TCRδ
V 50 57 14 3
D 0 2 0 3
J 70 13 5 3
C 1 2 2 1
aTCR, T cell receptor.
Jδ1 Jδ2Dδ1
δ locus
Dδ2 Cδ Cα3'5'
Vα2
5'
LGerm-lineα-chain DNA
Protein product αβ heterodimer
Rearranged β-chain DNA
Rearranged α-chain DNA
Germ-lineβ-chain DNA
VαnL
Vα1L Vα2L VαL
Vδ1L VδnL Vδ2L Jα1 Jα2 Jαn
5'
Dβ Jβ Cβ1 Dβ2 Jβ Cβ2VβL Vβ14LVβnL
Dβ Cβ1 Dβ2 JβJβ Cβ2
5'
VβL Vβ14LVβ
Dβ
SS
T cellCβJβVβ
L
Cα3'
3'
3'
Jα2 Jαn
Vα CαJα
Figure 6–2. Germ line and rearranged α and β T cell receptor (TCR) gene loci.
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1. There are several hundred V, D, and J segments that recombine randomly tocreate a pool of rearranged TCR V genes.
2. Imprecise joining and nucleotide addition add diversity. 3. Combinatorial association between the α and β or the γ and δ chains further
expands the repertoire. 4. TCR editing occurs infrequently, and there is no somatic hypermutation of
TCR V region sequences as there is for BCR V region genes.
TCR REARRANGEMENTS IN CANCER
• The molecular diagnosis of human T cell leukemias and lymphomas is greatly aided by showing thatthey are monoclonal and express a TCR with a uniform Vα or Vβ region.
• This can be accomplished by molecular techniques, such as the polymerase chain reaction (PCR), thatdemonstrate the proliferating cells have rearranged a uniform TCR Vα or Vβ segment.
• This type of molecular approach aids in early diagnosis and monitoring the status of the neoplasticclone during therapy.
D. The natural ligand for the TCR is a foreign peptide plus a host MHC molecule. 1. The TCR recognizes peptides derived from foreign protein antigens that are
bound to a major histocompatibility complex (MHC) molecule and presentedby an antigen-presenting cell (APC).
2. The complementarity determining regions (CDRs) of the TCR make contactwith amino acid residues of both the peptide and the MHC molecule (Figure6–1).
E. Superantigens produced by microbes can bind the TCR and the MHC outsidethe peptide-binding site. 1. Staphylococcus and Streptococcus species produce exotoxins that act as superanti-
gens.2. Microbial superantigens cross-link TCR Vβ regions to MHC class II molecules.3. Binding of superantigens to the TCR induces polyclonal activation of T cells.
TOXIC SHOCK SYNDROME
• Toxic shock syndrome (TSS) is a systemic disease associated with vaginal or surgical wound infec-tions with the gram-positive bacterium Staphylococcus aureus.
• S aureus produces a superantigen, called toxic shock syndrome toxin (TSST), which activates CD4+
T cells to produce massive quantities of inflammatory cytokines.
• The systemic nature of the inflammatory response manifests as fever, coagulopathies, extreme hy-potension, skin rash and exfoliation, and diarrhea.
F. Natural killer T (NKT) cells express an unusual form of the TCR.1. Invariant NKT cells (iNKT cells) express a uniform α chain composed of a
single Vα region called Vα24.2. The β chain of the iNKT cell TCR is created by recombination using only a
subset of the Vβ gene segments. 3. The known ligands of the iNKT cell TCR are glycolipids that are presented by
CD1 molecules, not MHC molecules (Chapter 7).4. iNKT cells produce cytokines and become cytotoxic when activated through
their TCR.
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CLINICALCORRELATION
CLINICALCORRELATION
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II. Optimum T cell activation by antigen requires TCR stimulation andsignals derived from the APC.A. Compared to antibodies, TCRs bind their ligands with relatively low affinity (Kd
104–105 M). B. The binding between a T cell and its APC is strengthened by the T cell adhesion
molecules LFA-1 and CD2 (Table 6–3).C. Coreceptors on T cells augment the intracellular signal transduction pathways
that are initiated by the TCR–CD3 complex. 1. Many coreceptors promote TCR signaling by phosphorylating immunotyro-
sine activation motifs (ITAMs) of CD3. 2. T cells that express TCR specific for peptide-MHC class II complexes use CD4
as a signaling coreceptor. 3. T cells that express TCR specific for peptide-MHC class I complexes use CD8
as a coreceptor.4. CD28 provides important coactivation signaling for T cells. 5. CD154 is a ligand for the CD40 coreceptor found on B cells.
D. Cytokines provide a second source of costimulatory signals (Chapter 12).
HYPER IGM SYNDROME
• Children with X-linked hyper IgM syndrome show elevated levels of serum IgM, but extremely lowconcentrations of IgG, IgA, and IgE.
• Their activated T cells lack CD154, which results in impaired Th cell function and B cell signaling.
• Impaired Ig class switching in B cells results in elevated IgM antibody levels.
• With the failure to produce opsonizing IgG antibodies, infections with pyogenic (pus-forming) bacteriaare common in these patients.
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CLINICALCORRELATION
Table 6–3. Adhesion molecules and coreceptors on T cells.a
T Cell Coreceptor Ligand on APC Cells That Express the Receptor Ligand
LFA-1 ICAM-1 Endothelial cells, many others
CD2 CD58 Many cells
CD4 MHC class II Dendritic cells, B cells, macrophages
CD8 MHC class I Nearly all nucleated cells
CD28 B7 Dendritic cells, activated B cells,macrophages
CD154 CD40 Dendritic cells, B cells, macrophages, others
aAPC, antigen-presenting cell; LFA-1, lymphocyte function-associated antigen 1; ICAM, intercellularadhesion molecule; MHC, major histocompatibility complex.
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III. Signaling through the TCR leads to gene transcription. A. The binding of the TCR to it ligand recruits the CD3 peptides to the αβ chains
via charge interactions in their transmembrane domains. B. ITAMs in the cytoplasmic tails of CD3 peptides are sites for the assembly of sig-
naling intermediates, including the kinase �-associated protein-70 kDa (ZAP-70) (Figure 6–3).1. ZAP-70 becomes phosphorylated and, in turn, phosphorylates phospholipase
C� (PLC�). a. PLCγ hydrolyzes the membrane phospholipid phosphatidylinositol 4,5-
biphosphate (PIP2) producing diacylglyceride (DAG) and inositol 1,4,5-triphosphate (IP3). (1) DAG activates protein kinase C (PKC), which activates the nuclear
factor-�B (NF�B) transcription factor pathway (Figure 6–4).(2) IP3 mobilizes intracellular Ca2+, which activates calmodulin. (3) Ca2+/calmodulin-dependent enzymes, including the phosphatase cal-
cineurin, are activated.(4) Calcineurin mediates dephosphorylation of the latent transcription fac-
tor nuclear factor of activated T cells (NFAT).2. ZAP-70 also phosphorylates adapter proteins that lead to the activation of the
G protein-mediated Ras/Rac pathways.a. Mitogen-activated protein (MAP) kinases are then activated.
Chapter 6: T Cell Recognition of and Response to Antigen 69
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Increase incytosolic Ca2+
Recruitment andactivation of PLCγ
Hydrolysisof PIP2
Activationof PKC
PP
P
PP
P
P
P
P P
PIP2DAG
LAT
CD4 TCR
ZAP-70PKC
LckItk
Transcriptionactivation
Ca ions PLCγ
PLCγ
IntracellularCa2+ stores
Activeprotein
IP3
Inactiveprotein
Calmodulinactivation
Figure 6–3. Intracellular signaling events accompanying T cell activation. PLC, phospholipase C; PIP2,phosphatidylinositol 4,5-biphosphate; PKC, protein kinase C; ZAP-70, ζ-associated protein-70 kDa;LAT, linker for activation of T cells; DAG, diacylglyceride; IP3, inositol 1,4,5-triphosphate.
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b. The MAP kinases phosphorylate and activate the AP-1 family of transcrip-tion factors (Figure 6–4).
C. The transcription factors NFκB, NFAT, and AP-1 act coordinately to initiate thetranscription of important T cell genes.1. NFAT regulates the transcription of the interleukin (IL)-2, IL-4, interferon
(IFN)-γ, and tumor necrosis factor (TNF)-α genes. 2. NFκB transcription factors induce the expression of the IL-2, IFN-γ, and
TNF-α genes. 3. AP-1 activates transcription of the IL-2 and many other cytokine genes.
CYCLOSPORINE AND TRANSPLANTATION
• Cyclosporine and the related drug FK-506 (Tracolimus) have proven effective in managing allograft re-jection episodes that are mediated by activated T cells.
• Both drugs inhibit the cellular phosphatase calcineurin and thereby diminish NFAT activation and cy-tokine gene expression.
• The use of these powerful immunosuppressive drugs has allowed clinical transplantation to be per-formed successfully even when some genetic disparity exists between donor and host (Chapter 17).
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CLINICALCORRELATION
Calcineurin
Ca2+
Calmodulin
CytoplasmicNFAT
Nucleus
ActiveNFκB
InactiveNFκB
ActiveNFAT
ActiveAP-1
Rac•GTPRas•GTP
IκB PIκB
P
P
IκB
IκB
PKC
fos gene
Jun
PP
ELK
Fos
Fos
ELK
ELK
P
PJun
P Jun
JNKERK
IL-2 geneIL-2 mRNA
Figure 6–4. Transcription factors that mediate T cell signaling. NF, nuclear factor; NFAT, nuclearfactor of activated T cells; GTP, guanosine triphosphate; ERK, extracellular signal-regulated kinase;JNK, Jun N-terminal kinase; IL, interleukin.
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D. Coreceptors augment signaling initiated by the TCR (Figure 6–3). 1. CD4 and CD8 binding to MHC molecules recruits the kinase Lck to the TCR
complex. 2. Lck then phosphorylates the CD3ζ ITAM residues, which promotes ZAP-70
recruitment to the complex. 3. CD28 coreceptor binding to its ligand, B7 on dendritic cells, recruits PLCγ to
the cell membrane. 4. TCR ligation in the absence of coreceptor signaling can lead to anergy (unre-
sponsiveness) in T cells.a. Clonal anergy is important in maintaining unresponsiveness to certain self
antigens (Chapter 16). b. Conversely, the loss of clonal anergy among T cells that bear receptors for
autoantigens can result in autoimmunity.
IV. The functions of antigen-activated T cells emerge after several cycles ofcell division and differentiation. A. Most activated CD4+ T cells express helper activity by secreting cytokines that act
on other immune system cells.1. The CD4+ T helper population can be further subdivided into the Th1 and
Th2 cell subsets based upon the cytokines they secrete (Table 6–4 and Figure6–5).
Chapter 6: T Cell Recognition of and Response to Antigen 71
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Table 6–4. Th1 and Th2 CD4+ T cell subsets.a
Cytokine Th1 Cells Th2 Cells Principal Functions
IL-2 ++ − Lymphocyte proliferation
IFN-γ ++ − Macrophage activationInhibition of IL-4 effects
LT (TNF-β) ++ − Cytotoxicity
GM-CSF ++ + Monocyte and dendritic cell differentiation
IL-4 − ++ B cell activation; Ig class switching; mast cellgrowth; inhibition of Th1 pathway
IL-5 − ++ B cell activation; Ig class switching; eosinophilgrowth and differentiation
IL-10 − ++ Inhibition of macrophage and lymphocyte activation
IL-13 − ++ Induction of mucus secretion; inhibition of IFN-γ action
aIL, interleukin; IFN, interferon; LT, lymphotoxin; TNF, tumor necrosis factor; GM-CSF, granulocytemacrophage colony-stimulating factor; Ig, immunoglobulin.
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a. The Th1 cell subset produces cytokines primarily associated with cell-mediated immunity (ie, cytotoxic T cell growth and macrophage activation).
b. The Th2 cell subset produces cytokines primarily associated with humoralimmunity (ie, B cell activation, proliferation, differentiation, and Ig classswitching).
2. Some of the cytokines produced by the two Th cell subsets promote the devel-opment of their respective subset. a. IL-4 is an important inducer of the Th2 response.b. IFN-γ favors the development of a Th1 response.
3. Each subset produces at least one cytokine that inhibits the functions of theother subset pathway (Figure 6–5). a. IL-10 and IL-4 produced by Th2 cells inhibit IL-12 production by APCs.b. IL-4 antagonizes the macrophage-activating effects of IFN-γ. c. IFN-γ produced by Th1 cells inhibits the proliferation of the Th2 cell sub-
set.d. IFN-γ antagonizes the B cell-activating effects of IL-4.
4. Dedicated transcription factors mediate the genetic control of Th1/Th2 devel-opment.a. T-bet is activated by IFN-γ and promotes Th1 cell development.b. GATA-3 favors the development of a Th2 cell response.
B. Several populations of T cells express cytotoxic activity against foreign target cells(Table 6–5).1. Conventional CD8+ cytotoxic T lymphocytes (CTL) kill targets expressing
foreign peptides and MHC class I molecules.2. Some CD4+ T cells are cytotoxic for targets expressing foreign peptides and
MHC class II molecules.
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Th1InhibitionInduction
Th2
Macrophageactivation
B cellactivation
Mast cellgrowth
IFN-γ
Th1 Th2
IL-3IL-10IL-12 IL-4 IL-5
Figure 6–5. Cross-regulation of the Th1 and Th2 cell subsets. IL, interleukin.
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3. iNKT cells are cytotoxic against cells expressing glycolipid antigens presentedby CD1 molecules.
4. All of these cytotoxic T cells require direct contact with their target cells andinduce death by apoptosis (Figure 6–6). a. CTL reorient their killing components toward the cellular pole in contact
with their target cell. b. Membrane-bound cytosolic granules of the cytotoxic cell then fuse with the
cell membrane. (1) Perforin is a granule protein that polymerizes in the target cell mem-
brane and facilitates the delivery of granzymes. (2) Granzymes are serine proteases that cleave caspases and initiate apopto-
sis in the target cell. c. Fas ligand, which is expressed on activated T cells and NKT cells, can in-
duce apoptosis. (1) Fas ligand binds to a widely distributed receptor called Fas.(2) Fas contains death domains that recruit and activate the cytosolic cas-
pases within the target cell. d. Cytotoxic cells secrete TNF-α and lymphotoxin (LT), which bind to TNF
receptors.(1) TNF receptors contain death domains that recruit adaptor proteins and
activate caspases. (2) TNF receptors can also activate transcription factors that regulate gene
expression (Chapter 12).5. After delivering a lethal hit, the cytotoxic cell dissociates from its target cell and
repeats the process with another target cell.
Chapter 6: T Cell Recognition of and Response to Antigen 73
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Table 6–5. Cytotoxic lymphocytes.a
Property CTL NKT Cell NK Cell
Receptors TCRαβ; TCRγδ Invariant TCRαβ a
Receptor ligands Peptides + Lipids and MHC class I glycolipids + CD1 a
Surface markers CD8 > CD4 CD8, CD4, and NK cell markers NK cell markers (eg, CD161)
Functions Cytotoxicity Cytotoxicity and Cytotoxicity and cytokine and cytokine cytokine productionproduction production
Pathogens Viruses and Unknown Virusesrecognized intracellular
bacteria
aFor a description of the diverse NK cell receptors and their ligands, see Chapter 10. CTL, cytotoxicT cells; NKT, natural killer T; NK, natural killer; TCR, T cell receptor.
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Granule exocytosis pathway
FAS pathway
CTL
Target cell
Extracellularspce
Granule
Granzyme
FAS ligand
FAS
FAS deathdomains
FADD
Initiator caspase
Caspase cascades
Apoptosis
Perforin poreCa2+
CTL CTL
Target cell
Granule
Perforinmonomers
Polymerized perforin
Completedpore
1
2
3
4 5 6
Nucleus
Figure 6–6. Conjugate formation and cell-mediated lysis by a cytotoxic T cell(CTL). (1) CTL-target cell contact, (2) granule fusion, (3) degranulation, (4) perforininsertion into target cell membrane, (5) polymerization of perforin, (6) pore forma-tion
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CLINICAL PROBLEMSInfection of cells with certain herpes viruses leads to a decrease in the expression of class IMHC molecules by the infected cells.
1. For which of the following cytotoxic cells would this decrease its ability to recognize thevirus-infected cell?
A. CD4+ T cell
B. CD8+ T cell
C. NK cell
D. NKT cell
E. NK and NKT cell
A patient in renal failure received a kidney transplant from an unrelated donor. The pa-tient was treated immediately with cyclosporine. Three weeks posttransplant, he devel-oped an infection with cytomegalovirus that was attributed to his immunosuppressivetherapy.
2. A decrease in which of the following responses would best explain this type of oppor-tunistic infection?
A. Transcriptional activation in B cells
B. Ca2+ mobilization in macrophages
C. Cytokine gene expression in T cells
D. Neutrophil chemotaxis
E. Signaling through the BCR
Ronald is a 2-year-old boy who presents with a 1-year history of recurrent sinus infectionscaused by gram-positive bacteria, including Group A streptococci. He has not had infec-tions with viruses or fungi. He was successfully treated with antibiotics in the past, but hisinfections often returned after treatment ended. Laboratory tests indicate an elevated titerof anti-A and anti-B isohemagglutinins, but an IgG level that is less than 5% of the nor-mal level for his age.
3. Which of the following mechanisms or diseases would be most consistent with thisclinical picture?
A. Bruton’s X-linked agammaglobulinemia
B. A deficiency of ZAP-70
C. DiGeorge syndrome
D. A lack of CD154 expression
E. HIV-1 infection
Mary is an 11-year-old child with asthma. Allergy skin testing has revealed allergic reac-tions to 10 different household and outdoor allergens.
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4. If you were to design an experimental therapy directed at reducing cytokine productionin this disease, which of the following cytokines would be the best target of this ther-apy?
A. IL-1
B. IL-2
C. IL-4
D. IL-8
E. IL-12
A patient with recurrent viral infections has normal numbers of blood lymphocytes, butthe cells do not express granzymes when activated in vitro.
5. A mutation in the gene encoding which of the following signaling intermediates wouldproduce this phenotype?
A. Lck
B. Fas
C. MyD88
D. ZAP-70
E. Btk
ANSWERS
1. The correct answer is B. Among the choices, only CD8+ T cells require MHC class Imolecules for their recognition of viral peptide antigens. The expression of this proteincan be inhibited by viruses that interfere with the synthesis of β2-microglobulin, whichis shared by MHC class I and CD1 molecules (Chapter 7).
2. The correct answer is C. Cyclosporine inhibits the phosphatase calcineurin, which isimportant in activating the transcription factor NFAT. NFAT regulates a number ofcytokine genes in T cells, including those that coinduce virus-specific CD8+ cytotoxicT cells to differentiate (eg, IL-2).
3. The correct answer is D. Elevated IgM antibody together with very low or absent IgGis an indication that the patient’s B cells do not switch Ig class efficiently. This is typi-cal of hyper IgM syndrome type 1, the congenital absence of CD154. The patient doesnot lack B cells, but fails to receive the proper signal from Th cells.
4. The correct answer is C. IL-4 plays a central role in the development of allergy by pro-moting Ig class switching to IgE and inducing more Th2 helper cells that produce IL-4.Mast cells are the source of inflammatory mediators in asthma, and their growth is alsopromoted by IL-4 (Chapter 13).
5. The correct answer is D. ZAP-70 deficiency causes a decreased signaling in both CD4+
and CD8+ T cells. Granzyme expression is a marker for activated cytotoxic lymphocytes.
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I. The principal function of the major histocompatibility complex (MHC)of genes is to regulate antigen recognition by T cells. A. In the thymus, MHC molecules determine the content of the T cell receptor
(TCR) repertoire. 1. Clones of thymocytes expressing TCRs that recognize foreign peptide antigens
presented by the host’s own MHC molecules are retained (Chapter 10). 2. Clones of thymocytes with TCRs that recognize peptide antigens presented by
nonhost MHC molecules are deleted.3. Mature thymocytes leave the thymus bearing TCRs capable of recognizing for-
eign peptides + self MHC in the periphery. B. In the postthymic environment, the MHC controls antigen recognition by ma-
ture T cells.1. The TCR recognizes antigenic peptides in the periphery only when they are
complexed with a self MHC molecule. a. Antigen recognition by T cells is “MHC restricted.”b. The TCR has a dual specificity for “altered self” (ie, self MHC + a foreign
peptide).2. MHC genes are immune response genes that determine the magnitude of T
cell activation by foreign protein antigens.C. MHC genes control the activation of natural killer (NK) cells by two mechanisms
(Chapter 10).1. MHC gene products present peptides to NK cell activating receptors.2. MHC glycoproteins are also recognized by inhibitory receptors that suppress
NK cell activation.D. The MHC serves as the most important genetic barrier to organ transplantation
between two unrelated individuals of a species.1. In organ transplantation, the MHC molecules on a donor’s tissues can be
viewed by the recipient’s T cells as foreign. a. In this context MHC molecules are alloantigens, antigens expressed by
some, but not all, members of a species. b. MHC alloantigens stimulate vigorous T cell responses leading to graft rejec-
tion (Chapter 17).
NC H A P T E R 7C H A P T E R 7
MAJOR HISTOCOMPATIBILITY
COMPLEX
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II. MHC genes encode two classes of polypeptides that control antigenrecognition by T cells.A. MHC class I gene products present foreign peptides to CD8+ T cells.
1. Antigen recognition by CD8+ T cells is restricted by MHC class I molecules.2. Only peptides bound to MHC class I molecules activate CD8+ T cells. 3. The three MHC class I genetic loci in human beings are called human leukocyte
antigen-A (HLA-A), HLA-B, and HLA-C.4. Each HLA class I gene encodes an ~45-kDa α polypeptide chain.
a. Class I α chains are always expressed on the cell surface noncovalently asso-ciated with a 12-kDa invariant chain called �2-microglobulin (Figure 7–1).
b. Class I α chains are integral membrane proteins with three external do-mains.(1) Amino acids within the membrane-distal α1 and α2 domains are highly
variable.
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CC
C
C
N
NN
Peptide-binding cleft
N
α2 β2
α1 β1
β2- α3
α1 α2
α2
α1
β1
Peptide-binding cleft
Peptide
Class I MHC
Class II MHC
α1
α1 α2
β2m α3
Microglobulin
Figure 7–1. Structure of major histocompatibility complex (MHC) molecules. β2m, β2-microglobulin.(Top: Adapted, with permission, from Bjorkman PJ: Structure of the human class I histocompatibilityantigen, HLA-A2. Nature 1987;329:506.) (Bottom: Adapted, with permission, from Brown JH: Three-dimensional structure of the human class II histocompatibility antigen HLA-DR1. Nature1993;364:33.)
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(2) The α1 and α2 domains determine the peptide-binding specificity andalloantigenicity of class I.
(3) The membrane proximal α3 domain and β2-microglobulin stabilize theoverall structure.
5. MHC class I molecules possess a single peptide-binding groove within the α1and α2 domains (Figure 7–1).a. Contact residues within the groove determine specificity.b. The typical peptide that binds to a class I molecule is 9–11 amino acids in
length.c. MHC class I-binding peptides contain terminal hydrophobic residues that
anchor them into the groove.d. Each MHC class I molecule shows “promiscuous binding” in that it can
bind several different peptides.B. The principal function of MHC class II molecules in the periphery is to present
peptide antigens to CD4+ T cells. 1. Antigen recognition by CD4+ T cells is MHC class II restricted.2. Only foreign peptides bound to MHC class II molecules can activate CD4+ T
cells. 3. The MHC class II genes in human beings are found in three genetic regions
called HLA-DP, HLA-DQ, and HLA-DR. 4. Each class II genetic region contains one or more α and β genes.
a. The class II α and β loci encode for 33- and 28-kDa polypeptide chains, re-spectively.
b. The class II molecules form αβ heterodimeric cell surface glycoproteins(Figure 7–1).
c. Each chain has a membrane-distal domain (ie, α1 or β1) that is highly vari-able.
d. The α1 and β1 domains of class II molecules contain the peptide-bindinggroove.
e. These regions of sequence variability also prescribe the alloantigenic natureof class II molecules.
5. The peptide-binding groove of a typical class II molecule is similar in structureto that of a class I molecule.a. Contact residues in the binding groove determine binding specificity. b. MHC class II molecules typically bind 12–15 amino acid peptides that can
extend beyond the limits of the groove.c. Like class I, class II molecules show binding promiscuity.
C. Class I and class II MHC genes belong to the Ig supergene family.D. MHC class III genes do not control T cell activation directly.
1. Class III genes include those for the complement proteins C2, C4, and FactorB (Chapter 8).
2. The gene for tumor necrosis factor (TNF)-α is also found in the class III MHCfamily.
ALTERED MHC-BINDING PEPTIDE LIGANDS
• The nature of a T cell response to a peptide antigen can be altered by changing only a few of the con-tact residues of the peptide that interact with the TCR.
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• These altered peptide ligands include “superagonistic” peptides that can enhance T cell activation,which would be useful in designing antitumor immunotherapy.
• Similarly, altered peptide ligands can theoretically be designed that would inhibit unwanted T cell acti-vation, such as that seen in autoimmune diseases.
III. MHC molecules show extensive functional diversity due to polygeny andgenetic polymorphism.A. Polygeny refers to the existence of multiple genetic loci that have similar func-
tions. 1. Three MHC class I gene loci, HLA-A, HLA-B, and HLA-C, control antigen
presentation to CD8+ T cells.2. Many MHC class II genetic loci control antigen presentation to CD4+ T cells
(eg, DPa1, DPa2, DPb1, and DPb2). 3. The existence of multiple MHC gene products increases the number of foreign
peptides that can be presented to T cells. B. Polymorphism within the MHC refers to the existence of multiple alleles of a
gene within a population (Table 7–1). 1. Each class I allele encodes an α chain.2. Each class II allele encodes either an α or a β chain. 3. A diploid individual can express at most two allelic products at each MHC
locus (ie, in the heterozygote).4. The β2-microglobulin gene is not polymorphic.5. Polymorphism has a greater effect on HLA diversity within the species than
within an individual (Table 7–2). a. Thus, in the human population there is the capacity to present an enormous
number of antigenic peptides.b. Each individual of that population has a much narrower potential repertoire
of MHC-encoded molecules.C. HLA diversity is sufficient for recognizing most protein antigens.
1. Each allelic product (eg, HLA-A1) can bind multiple peptides.2. Each cell expresses multiple allelic forms (Figure 7–2).
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Table 7–1. Examples of polymorphism at the HLA loci.
MHC Class HLA Locus Number of Alleles
I HLA-A 250I HLA-B 490I HLA-C 119
II HLA-DPA1 20II HLA-DPB1 99II HLA-DQA1 22II HLA-DQB1 53II HLA-DRB1 315II HLA-DRB3 38
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3. Mounting a successful response to a limited number of antigenicepitope–MHC complexes is apparently adequate to protect the host.
IV. MHC genes are inherited as a closely linked group of loci and arecodominantly expressed (Figure 7–3).A. HLA class I loci are clustered at the 3′ end of the complex on chromosome 6.
1. Each class I locus encodes an α chain, which is paired with β2-microglobulinprior to surface expression (Figure 7–4).
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Table 7–2. The basis for diversity among immunoglobulins and MHC molecules.
Feature Immunoglobulin Genes MHC Genes
Repertoire of an ~104 genes; ~109 Igs 6 class I allelesindividual 6 class II alleles
Repertoire of the ~104 genes; ~109 Igs > 400 class I allelesspecies > 500 class II alleles
Diversity mechanisms Large pools of germ-line Heterozygosity V, D, J segments Codominant expression
Combinatorial joining of PolygenyV, D, J segments Polymorphism
Imprecision in joining sitesNucleotide additions at
joining sitesSomatic hypermutationCombinatorial association
of H and L polypeptides
A1A3
B2
DP15
DQ7
DQ3
DR7DR3 C2
C1
DP1
B7
C2 C1
B2B7A1
A3
Macrophage Fibroblast
Figure 7–2. Patterns of expression of HLA class I and class II genes.
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B. The class II loci are clustered at the 5′ end of the complex and code for either an αor a β chain.1. Different α and β gene products from a given region (eg, DP) can pair with
one another to form heterodimeric products.2. Additional loci between the DP and DQ regions encode proteins that function
in antigen presentation (see below). C. The closely linked genes of the MHC are inherited in a Mendelian fashion.
1. The constellation of linked MHC genes on a given chromosome is called ahaplotype (Table 7–3).
2. Haplotype inheritance ensures that certain predictions can be made about HLArelationships within families (Figure 7–5).a. Assuming no genetic recombination has occurred, parents are always hap-
loidentical with their children.b. Each child has a 75% chance of haploidentity with a sibling.c. Each child has a 25% chance of complete HLA identity with a sibling.
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Class II MHC lociHuman: HLA (chromosome 6)
Mouse: H2 (chromosome 17)
DP
Proteasome genes;TAP 1, 2
Complementproteins: C4,Factor B, C2
Cytokines:LTβ, TNF-α,LT
Class I-like genesand pseudogenes
DQ DR B C“Class III” MHC loci Class I MHC loci
Class II MHC loci “Class III” MHC loci Class I MHC lociClass IMHC locus
ADM
K I-A I-E D LDM
Figure 7–3. Genetic map of the HLA complex. MHC, major histocompatibility complex; TAP, trans-porter in antigen processing; LT, lymphotoxin; TNF, tumor necrosis factor.
Principal loci
HLA: B X E JC A H
HLA-A,B,C heterodimers
β2-microglobulin
Figure 7–4. HLA class I heterodimers.
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D. Individuals inherit parental MHC genes in their germ line DNA.1. The specificity of an individual’s T cells is an inherited trait. 2. The MHC loci do not rearrange prior to expression (Table 7–2).
E. MHC loci are expressed in a codominant fashion (Figure 7–2).1. All six allelic products of the HLA class I loci are expressed in the heterozygote.
a. Each MHC class I heterodimer is expressed on all nucleated cells, exceptcells of the trophoblast.
b. Any nucleated cell that expresses MHC class I molecules can present peptideantigens to CD8+ T cells.
c. Each MHC class II heterodimer is expressed on all dendritic cells, B cells,and macrophages.
d. Any such cell can present peptide antigens to CD4+ T cells.
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Table 7–3. Nomenclature of the HLA genetic system.
Term Definition Example
Region A region within the HLA complex HLA-DRcontaining related genes
Locus An open reading frame that encodes HLA-DRB1 (encodes a β chain of for an HLA peptide HLA-DR)
Allele One of the alternative sequences HLA-DRB1*0101at a locus
Antigen A cell surface heterodimeric protein HLA-DR1
Haplotype The constellation of linked genes HLA-A1, B2, C5, DP2, DQ1, DR4across the entire HLA complex on one chromosome
Father
A1, B12, DR5 =
a
b
A1, B2, DR4 =
Mother
A7, B7, DR6 =
c
d
a c b ca d b d
A3, B7, DR6 =
Figure 7–5. Inheritance of HLA genes within a family.
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F. The expression of MHC class II genes is coordinately controlled by tissue-specifictranscription factors, including the class II transactivator (CIITA).1. Constitutive expression of MHC class II is seen in B cells, monocytes,
macrophages, and dendritic cells (“professional antigen-presenting cells”).2. Several other cell types (eg, epithelial cells) can be induced to express class II
molecules by inflammatory signals.
COORDINATED EXPRESSION OF MHC CLASS II
• An autosomal recessive condition expressed in infants called bare lymphocyte syndrome (BLS) type2 is characterized by lymphopenia, diarrhea, and a variety of opportunistic infections.
• These patients have significantly decreased numbers of blood CD4+ T cells, and show decreased cellu-larity in their peripheral lymphoid tissues.
• HLA-DP, DQ, and DR molecules are essentially absent from their tissues.
• In many BLS type II patients, the expression of CIITA is defective.
V. Two distinct pathways of antigen presentation ensure that foreignpeptide antigens are presented by the proper MHC molecule to theappropriate T cell subset (Table 7–4 and Figure 7–6). A. Intracellular microbes (eg, viruses and intracellular bacteria) express protein anti-
gens that are presented on class I molecules to CD8+ T cells.1. Antigen presentation involves the degradation of these foreign proteins follow-
ing their synthesis within the cytosol. 2. The resulting peptides are directed to newly synthesized class I molecules in the
endoplasmic reticulum.
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Table 7–4. Pathways of antigen processing and presentation.a
Source Essential Cellular Pathway of Antigen Components Typical Antigens Processed
Class I Endogenous MHC class I α chains Viral capsule proteins and β2-Microglobulin nucleoproteinsUbiquitin Proteins derived from Proteasome intracellular bacteriaTAP-1,2Chaperones (calnexin,
tapasin, calreticulin)
Class II Exogenous MHC class II α and Proteins derived from β chains extracellular pathogens
Ii chain Traditional protein vaccinesCLIPHLA-DM
aTAP, transporter associated with antigen processing; CLIP, class II-associated invariant chain peptide.
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Production ofproteins inthe cytosol
Virus incytoplasm
Synthesizedviral protein
PolyribosomesProteasome TAP
Class I MHCα chain
ER
Peptides
Exocyticvesicle
β2m
Ubiquitinatedprotein
Proteolyticdegradationof proteins
Transport ofpeptides fromcytosol to ER
Assembly ofpeptide-Class Icomplexes in ER
Surface expressionof peptide-class I MHCcomplexes
1 2 3 4 5
CD8+ cytolyticT lymphocyte
CD8+Golgi
Uptake ofextracellularproteins intovesicularcompartmentsof APC
Endosome
Lysosome
Proteinantigen
ER
Exocyticvesicle
α
β
Ii
Processing ofinternalizedproteins inendosomal/lysosomalvesicles
Biosynthesisand transportof class II MHCmoleculesto endosomes
Associationof processedpeptides withclass II MHCmolecules invesicles
Expression ofpeptide-class IIMHC complexeson cell surface
1 2 3 4 5
CD4+ helperT cell
CD4
CLIP
DM
Golgi
Figure 7–6. Antigen processing by the class I and class II pathways. ER, endoplasmic reticulum; TAP,transporter associated with antigen processing; MHC, major histocompatibility complex; CLIP, classII-associated invariant chain peptide.
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3. These endogenous protein antigens are expressed on MHC class I and recog-nized by CD8+ T cells.
B. Extracellular microbes activate CD4+ T cells by expressing antigenic peptidesthat are presented on MHC class II molecules. 1. The uptake of these exogenous antigens can be accomplished by phagocytosis,
endocytosis, or receptor-mediated endocytosis. 2. Antigen processing and presentation require an intracellular pathway that de-
grades proteins within an endosome.3. The resulting peptides are directed to an exocytic vesicle containing newly
synthesized class II molecules. 4. These exogenous protein epitopes are then presented by the class II molecules
to CD4+ T cells.C. Components of the class I (endogenous or cytosolic) antigen presentation
pathway are dedicated to proteolysis, peptide sizing, peptide transport, and pro-tein targeting.1. The foreign protein antigen is first covalently attached to the small peptide
ubiquitin via the ε-amino group of lysine residues of the antigen molecule(Figure 7–6).
2. Ubiquitination targets the protein for degradation by the multicatalytic pro-teasome.a. The proteasome subunits LMP-2 and LMP-7, in part, determine substrate
cleavage specificity. b. LMP-2 and LMP-7 are encoded by genes in the MHC (Figure 7–3). c. Peptides that leave the cylindrical proteasome vary in size and charge.
3. Peptides that will fit the binding groove of MHC class I molecules are trans-ported from the cytosol to the endoplasmic reticulum.a. The transporter associated with antigen processing (TAP) complex me-
diates peptide transport across the ER membrane.b. TAP selects peptides of the appropriate length (9–11 amino acids) with hy-
drophobic ends.c. The genes encoding the TAP complex, TAP-1 and TAP-2, reside in the
MHC (Figure 7–3). 4. Newly synthesized MHC class I α chains are present in the ER membrane as-
sociated with β2-microglobulin and the chaperone proteins calnexin, tapasin,and calreticulum.a. Chaperones direct the trafficking of MHC class I molecules to the TAP
complex.b. Dissociation of the chaperones enables the loading of peptides into the
MHC class I molecules.5. The MHC class I–peptide complex is then directed to the membrane for ex-
pression. a. The absence of β2-microglobulin precludes surface expression of MHC class
I molecules.b. The absence of a peptide in the binding groove of MHC class I prevents its
surface expression. c. Pathogenic intracellular microbes often block the class I pathway by inhibit-
ing β2-microglobulin synthesis or TAP function.
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6. In the absence of foreign antigenic peptides, MHC class I molecules are alwaysloaded with self peptides.
BARE LYMPHOCYTE SYNDROME TYPE 1
• Mutations in either the TAP1 or TAP2 gene prevent the transport of cytosolic peptides into the ER andresult in incomplete peptide loading.
• Patients with these mutations do not express HLA-A, B, and C molecules on their nucleated cells, be-cause class I molecules cannot be expressed unless they are loaded with peptide.
• These patients also fail to develop CD8+ T cells due to a defect in positive selection in the thymus (Chap-ter 10).
• The resulting immunodeficiency is not as severe as severe combined immunodeficiency (SCID), but canlead to opportunistic viral infections.
• Patients with BLS type 1 generally show normal numbers of circulating lymphocytes due to the normaldevelopment of the CD4+ T cell subset.
D. Peptides presented by MHC class II molecules are generally derived from extracel-lular proteins that are taken up by antigen-presenting cells.1. Following uptake into an endocytic or phagocytic vesicle, the organelle be-
comes increasingly acidic with time. 2. Hydrolytic enzymes of the endolysosomes and phagolysosomes mediate prote-
olysis of the antigen. 3. These vesicles then fuse with exocytic vesicles containing newly synthesized
MHC class II molecules. a. Newly synthesized class II molecules are associated with a chaperone mem-
brane protein called the invariant chain (Ii) . b. Ii ensures proper folding and protects the binding groove of the class II het-
erodimer.4. When the vesicles fuse, the Ii chain is degraded into a small peptide, called a
class II-associated invariant chain peptide (CLIP). 5. HLA-DM catalyzes the removal of CLIP and the binding of appropriately
sized antigenic peptides.6. The loaded MHC class II molecule is then directed to the cell surface.
VI. There are notable associations between specific HLA phenotypes and thesusceptibility for certain diseases (Table 7–5). A. The relative risk of hereditary hemochromatosis is higher in individuals with the
HLA-A3 + B14 haplotype than in the general population. 1. Persons with this haplotype have an elevated incidence of mutations in a non-
classical MHC class I molecule called HLA-H (also known as HFE). 2. HLA-H appears to regulate the function of the transferrin receptor, thereby af-
fecting the absorption of dietary iron in the stomach and small intestine. 3. Thus, certain mutations in HLA-H result in a chronic systemic exposure to ex-
cess iron resulting in hereditary hemochomatosis.B. HLA associations are particularly common among autoimmune diseases.
1. HLA-B27 expression is associated with an increased relative risk of spondy-larthropathies.
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a. Spondylarthropathies are characterized by inflammation of the joints andcharacteristic extraarticular tissues.
b. Individuals expressing HLA-B27 have an increased relative risk of develop-ing the autoimmune conditions ankylosing spondylitis and Reiter’s syn-drome (Table 7–5).
c. Relative risk is the prevalence of the disease in those carrying the HLAmarker compared to the prevalence of the disease among the general popula-tion.
d. A number of microbial antigens cross-react with HLA-B27–peptide com-plexes, suggesting an infectious etiology for these autoimmune diseases.
CLINICAL PROBLEMSThe HLA genetic system was used in a civil case to resolve a paternity suit. The case in-volved a woman who sued an acquaintance for child support for her newborn twins. Thecourt ordered tissue typing (serological identification of the HLA markers; Chapter 17) ofthe mother, the two children, and the defendant. Partial results of the typing are shownbelow.
Individual HLA-A Markers HLA-B Markers
Mother 1,2 8,12
Son 1,3 8,7
Daughter 2,5 12,9
Defendant 3,3 7,28
1. Assuming there has been no recombination within the HLA complex, which haplotypedid the son inherit from his mother?
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Table 7–5. Disease associations with HLA phenotypes.
Disease HLA Antigen or Haplotype Relative Risk
Hereditary hemochromatosis HLA-A3 + HLA-B14 90
Ankylosing spondylitis HLA-B27 90
Reiter’s syndrome HLA-B27 37
Gluten enteropathy HLA-DR3 12
Rheumatoid arthritis HLA-DR4 14
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A. HLA-A1 + HLA-A2
B. HLA-A1 + HLA-B7
C. HLA-A1 + HLA-B8
D. HLA-A3 + HLA-B7
E. HLA-B8 + HLA-B7
2. Assuming no recombination within the HLA complex, which haplotype did thedaughter inherit from her mother?
A. HLA-2 + HLA-B12
B. HLA-2 + HLA-A5
C. HLA-B12 + HLA-B9
D. HLA-A2 + HLA-B9
E. HLA-A5 + HLA-B12
3. Which of the following is a paternal haplotype that could have been inherited by one ofthe children from the defendant?
A. HLA-A3 + HLA-B7
B. HLA-A1 + HLA-B8
C. HLA-A2 + HLA-B9
D. HLA-A5 + HLA-B9
E. HLA-A1 + HLA-B7
4. Based on these data alone, which of the following could be true?
A. The son cannot be related to the defendant.
B. The daughter cannot be related to the defendant.
C. Neither child is related to the defendant.
D. Both children could be related to the defendant.
E. The two children have different fathers.
Below is a pedigree showing the HLA phenotypes of the Smith family. This is the secondmarriage for both the father and the mother.
5. Which of the five children shown here is most likely the child of a previous marriageinvolving the mother?
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MotherHLA-A5, A7HLA-B28, B32
FatherHLA-A1, A7HLA-B8, B12
Son #1HLA-A1, A5HLA-B12, B28
Son #2HLA-A1, A5HLA-B12, B28
Son #3HLA-A1, A5HLA-B8, B28
Daughter #1HLA-A1, A7HLA-B8, B32
Daughter #2HLA-A1, A7HLA-B3, B32
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James is a 13-year-old child in need of a kidney transplant. He is the third of 14 childrenall with the same parents.
6. What are the chances that one of his siblings will be fully HLA compatible with James?
A. There is almost no chance this will occur.
B. 1 chance in 13
C. 1 chance in 4
D. 1 chance in 2
E. All of his siblings would be HLA compatible.
ANSWERS
1. The correct answer is C. A haplotype is a group of linked genes (eg, HLA-A1 + HLA-B8) on one chromosome. In this case, the maternal haplotype can be derived by notingthat these are the only HLA antigens shared between the mother and the son.
2. The correct answer is A. As with the son, these are the only HLA antigens shared withthe mother. Thus, the son and daughter define the two maternal haplotypes, HLA-A1+ B8 and HLA-A2 + B12.
3. The correct answer is A. If A1, B8, A2, and B12 are of maternal origin, then the re-maining HLA antigens were derived from the father. What is surprising in this case isthat only the HLA-A3 + HLA-B7 haplotype is represented in the defendant’s type.
4. The correct answers are B and E. Based on HLA typing it is safe to conclude that thedaughter is not related to the defendant. Because these children are fraternal twins, itcan only be concluded that the two children had different fathers. This is a case of ap-parent superfecundity, which occurs when two ova are produced during one ovulationcycle and become fertilized by sperm from two different fathers.
5. The correct answer is daughter #2. Analysis of the pedigree indicates that the haplo-types of the father are A1 + B8 and A7 + B12. The mother’s haplotypes are A7 + B32and A5 + B28. Daughter #2 bears the maternal haplotype A7 + B32, but the paternalhaplotype does not correspond to those of the father. Therefore, the child must befrom a previous marriage.
6. The correct answer is C. Based on Medelian inheritance in a codominant system, thereis a 25% chance of full haplotype identity between siblings, assuming no recombina-tions or mutations.
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I. Complement is a primitive immune effector and amplification systemconsisting of more than two dozen serum proteins.A. Complement components are designated by a “C” followed by a number (eg, C1)
or the word “Factor” followed by an upper case letter (eg, Factor B).B. The biological functions of complement include cell membrane lysis, opsoniza-
tion, activation of inflammatory responses, clearance of immune complexes, andB cell activation.1. Many of the biological activities are mediated by cell surface complement re-
ceptors. 2. The complement system can be activated during either innate or adaptive im-
mune responses. C. Complement system proteins become enzymatically or biologically active when
they are cleaved, form multimers, or bind to other biomolecules.
II. The complement system can be activated by three different pathways(Table 8–1).A. In each pathway, complement is activated by the recognition of molecular pat-
terns, on either antibody molecules or microbial components. B. All three activation pathways share a set of core elements that includes C3, C5,
and the so-called terminal components C6–C9 (Figure 8–1).1. Initiation of each of the pathways requires recruitment or assembly of a serine
protease.2. The critical second step is the cleavage of C3 by C3 convertase to form the
peptide fragments C3a + C3b.3. Then C5 is cleaved by a C5 convertase. 4. Amplification at each step results from the cleavage of multiple substrate mol-
ecules by these two convertases.C. The three pathways can be distinguished by their processes of initiation, their
unique components, their unique functions, and the manner by which they areregulated (Table 8–1).
D. The classical pathway of complement activation is initiated by antigen–anti-body complexes.1. Only immunoglobulin (Ig) M and IgG antibodies participate in classical path-
way activation.
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C H A P T E R 8C H A P T E R 8
COMPLEMENT
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2. Activation begins with the binding of the C1q peptide to the CH domains of µand γ heavy chains (Figure 8–2).a. C1q is a hexamer that cross-links two adjacent binding sites located on the
CH domains of µ or γ Ig heavy chains. b. IgM antibodies are more efficient than IgG antibodies in binding C1q, be-
cause the pentameric nature of IgM ensures that two CH domains will be inclose proximity to one another.
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Table 8–1. Three pathways of complement activation.a
Property Classical Pathway Lectin Pathway Alternative Pathway
Initiating factors IgG- or IgM-containing Microbial mannose Highly charged surfacesimmune complexes residues
Unique C1, C2, C4 MBL, MASP Factor B, Factor D, Factor P, components Factor H
C3 convertase C4b2a C4b2a C3bBb
C5 convertase C4b2a3b C4b2a3b C3bBb3b
Unique functions Adaptive immunity Innate immunity Innate immunity; positive feedback amplification;
C3 tickover function
Unique regulators C1 Inh Factor H
aIg, immunoglobulin; MBL, mannose-binding lectin; MASP, MBL-associated serine protease; C1 Inh, C1 inhibitor.
Membraneattack complex
C3 convertase C5 convertase
Majoramplification
step
Classicalpathway
Lectinpathway
Alternativepathway
C3 C3b C5bC5C6
C7
C8
C9
Figure 8–1. The core elements shared by the three pathways of complement acti-vation.
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3. Once bound, C1q recruits two copies each of C1r and C1s to form an activeenzyme.
4. The C1qr2s2 complex can cleave C4 to yield peptides C4a and C4b.1
5. C1qr2s2 then cleaves C2 to yield the C2a + C2b peptides.a. C2a binds to C4b to produce C4b2a, the classical C3 convertase. b. This enzyme complex can cleave C3 to yield C3a + C3b.
6. Multiple copies of peptides are produced at each cleavage step.
HEREDITARY ANGIOEDEMA
• Hereditary angioedema is a autosomal dominant trait characterized by acute, nonpainful, nonpru-ritic, and nonerythematous swelling of the skin and mucous membranes.
• Edema of the bowel wall can be painful, and laryngeal swelling is potentially life-threatening due toasphyxiation.
• The genetic defect is a decrease or absence of the complement regulatory protein, C1 Inhibitor (C1Inh), that regulates C1qr2s2, Hageman factor, kallikrein, and plasmin.
• Unabated complement activation through the classical pathway appears to contribute to the acuteangioedema, although the precise biochemical mediator has not been defined.
E. The lectin pathway of complement activation shares properties and compo-nents with the classical pathway (Figure 8–2).
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+C4
C2
Classical pathway
C1qr2s2
C4b2a
+C4
C2
Lectin pathway
MBL-MASP
Factor
C4b2a
C3
Alternative pathway
C3bB
Factor D
C3b orC3 (H20)
C3bBb
B
Figure 8–2. The initiation steps in the three pathways of complement activation.MBL–MASP, mannose-binding lectin–MBL-associated serine protease.
1A common convention in the complement field is the use of an overbar to designate enzymati-cally active complement components or complexes (eg, C1qr2s2 or C4b2a). For simplicity, thisconvention has been omitted here.
CLINICALCORRELATION
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1. Activation is initiated by the binding of mannose-binding lectin (MBL) tomicrobial carbohydrate residues. a. MBL is another name for mannose-binding protein (Chapter 1). b. MBL recruits and binds MBL-associated serine protease (MASP), an en-
zyme with substrate specificity similar to that of C1qr2s2. 2. MASP cleaves C4 and C2 to form the lectin pathway C3 convertase, C4b2a.
F. The alternative pathway of complement activation is initiated by at least threedifferent mechanisms (Figure 8–2). 1. Highly charged microbial surface patterns, including polysaccharides, can bind
C3.2. In fluid phase, C3 can spontaneously hydrolyze with water to form an interme-
diate designated C3(H2O). 3. The C3b peptide, derived from the classical or lectin pathways, can activate the
alternative pathway directly. 4. Bound C3, C3(H2O), or C3b then binds Factor B.5. Bound B is then cleaved by the constitutively active enzyme Factor D to pro-
duce Ba + Bb.6. C3Bb, C3(H2O)Bb, and C3bBb are the alternative pathway C3 convertases.
a. Whereas C3(H2O)Bb is unstable, the other two complexes are relatively sta-ble.
b. C3bBb can be further stabilized by binding Factor P. 7. The ability of the alternative pathway C3 convertases to generate more C3b
constitutes a feedback amplification loop (Figure 8–3).
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Any C3bsource
Factor D
C3b
C3b
C3bBb (C3 convertase)
B
Ba
C3
C3a
Figure 8–3. The positive feedback amplification loop of the alternative pathway.
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8. Another unique feature of the alternative pathway is called C3 tickover.a. C3 constantly interacts with H2O in fluid phase to form C3(H2O), an ini-
tiator of alternative pathway activation.b. However, the C3(H2O) intermediate is very unstable.
G. The peptides C3b and C4b can establish stable sites for further complement acti-vation by covalently binding to appropriate surfaces.1. C3b and C4b contain internal thioester bonds that can be rearranged to form
ester or amide linkages with biomolecules. 2. These sites also provide covalently attached ligands for complement receptors.
III. The terminal steps in complement activation are shared by the threepathways.A. C3 convertases are converted to C5 convertases by the binding of C3b (Table
8–1). B. The C5 convertases cleave C5 generating C5a + C5b.
1. C5a is a biologically active peptide that mediates chemotaxis and mast cell acti-vation (see below).
2. C5b is the first component of the membrane attack complex (MAC) (Figure8–4). a. The assembly of the MAC does not require proteolysis.b. The assembled C5b678 complex can intercalate into the lipid membranes of
both microbial and host cells.c. The C5b678 complex recruits multiple copies of C9 to form a stable mem-
brane pore.d. Membrane disruption and rapid cell lysis result.
IV. The activation of complement is controlled at several levels (Table 8–2).A. Some regulatory elements inhibit the formation of or dissociate active enzyme
complexes. 1. Many such inhibitors (eg, C1 Inh and C4b-BP) block early pathway initiation.2. Other inhibitors prevent the inadvertent lysis of host cells.3. Components, such as HRF, CD59, or decay accelerating factor (DAF), are
species specific and block complement activation on host, but not microbial,membranes.
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C5b C5b67
C5b678
Membrane attack complex
Poly-C9C9C8C6
C7
Figure 8–4. Terminal steps in complement activation.
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B. Several regulatory factors inactivate biologically active complement peptides byproteolysis.1. Anaphylatoxin inhibitor (AI) cleaves the terminal arginine residues of pep-
tides C3a, C4a, and C5a, rendering them inactive.2. Factor I cleaves C3b and C4b, destroying their ability to form C3 convertases.
C. Some factors (eg, S protein) prevent membrane attack by blocking the assemblyof a mature MAC.
TRANSGENIC PIGS, MEMBRANE ATTACK, AND XENOTRANSPLANTATION
• The worldwide shortage of organs suitable for clinical transplantation has stimulated research on thetransplantation of organs between species (xenotransplantation).
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Table 8–2. Regulation of the complement system.
Regulator Pathway Affected Mechanism of Action
C1 inhibitor Classical A serine protease inhibitor that dissociates (C1 Inh) C1r2s2 from C1q
C4b-binding Classical Prevents formation of the classical and lectin protein (C4bBP) pathway C3 convertase by blocking binding of
C4b to C2a
CR1 All Prevents formation of C3 convertases byblocking the binding of C3b to Factor B orthe binding of C4b to C2a
Factor P Alternative Stabilizes C3bBb
Factor H Alternative Blocks formation of C3bBb by binding to C3b
Decay All Accelerates the decay of the C3 convertases accelerating C4b2a and C3bBbfactor (DAF)
Factor I All Cleaves C3b and C4b to produce iC3b andiC4b, respectively
Anaphylatoxin All Cleaves and inactivates the anaphylatoxins inhibitor (AI) C3a, C4a, and C5a
S protein All Prevents membrane insertion of the C5b67complex
Hemologous All Prevents binding of poly-C9 to the C5b678 restriction complexfactor (HRF)
CLINICALCORRELATION
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• The early rejection of xenografts, including pig grafts in human beings, appears to be mediated by nat-ural human antibodies and complement.
• The membranes of pig cells appear to be particularly susceptible to membrane attack, because theircomplement regulatory proteins do not inhibit human complement components (eg, C3 convertasesand MAC).
• A novel approach to this dilemma has been to create transgenic pigs expressing human complementregulatory proteins (eg, DAF).
• If successful, these animals could be developed as a source of organs for clinical transplantation.
V. The biological activities of the complement system depend on the actionof its peptides and assembled complexes (Table 8–3). A. Membrane damage is caused by the assembly of the MAC in a lipid bilayer.
1. This is an important mechanism of host cell lysis in transfusion reactions,transplantation rejection, and autoimmunity.
2. The MAC can lyse the exposed outer membranes of Gram-negative bacteria.3. Membrane damage caused by MAC is similar to that caused by perforin pro-
duced by cytotoxic T cells (Chapter 6).a. Poly-C9 and poly-perforin produce membrane pores.b. Perforin and C9 show considerable amino acid sequence homology.
FACTOR I DEFICIENCY
• Because Factor I destroys C3 convertases by cleaving C3b and C4b, it regulates complement activationat a key amplification step.
• The importance of Factor I in this regard is illustrated by individuals with hereditary Factor I deficiency.
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Table 8–3. Summary of important complement components and complexes.a
Classical Pathway Lectin Pathway Alternative Pathway
Enzymatic C1qr2s2 MBL-MASP Factor Dcomponents C4b2a C4b2a C3bBb
C4b2a3b C4b2a3b C3bBb3b
Biologically active C3b C3b C3bpeptides or C4b C4b C4bcomplexes C3d C3d C3d
C3a C3a C3aC4a C4a C4aC5a C5a C5aC5b-9n C5b-9n C5b-9n
Important C1 Inh C4b-BP Factor Pregulatory C4b-BP Factor I Factor Icomponents Factor I Factor H
aMBL-MASP, mannose-binding lectin-MBL-associated serine proteases; C1 Inh, C1 inhibitor; C4b-BP,C4b binding protein.
CLINICALCORRELATION
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• These patients suffer from recurrent pyogenic infections, including meningococcal meningitis.
• The treatment of these patients with recombinant Factor I provides some relief during acute infections,but its long-term clinical effectiveness is unknown.
B. Many complement peptides exert their biological effects through cell surface com-plement receptors (CR) (Table 8–4).1. Complement receptor 1 (CR1) mediates the clearance of circulating immune
complexes that bear C3b or C4b.a. Erythrocytes bear the highest densities of CR1 and mediate the greatest
share of immune complex clearance. b. The complexes are delivered to the liver, where they are taken up by Kupffer
cells.2. CR2 mediates B cell coactivation when C3d-coated antigens cross-link CR2
and BCR (Figure 8–5).3. The opsonic activity of C3b, iC3b, C4b, and iC4b is due to the binding of
particles coated with these peptides to CR1, CR3, and CR4. 4. The C3a/4a receptor (CR3a/4aR) mediates mast cell degranulation (Chapter
13).5. C5aR is a G protein-coupled seven transmembrane chemotactic receptor that
mediates the chemoattraction of neutrophils.C. Microbes have developed elaborate mechanisms of immune evasion by targeting
the complement system and diminishing its biological activities.1. Herpes simplex virus produces a glycoprotein (C) that promotes C3 decay.
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Table 8–4. Complement receptors.
Complement Cell Expressing Principal Biological Receptor Ligands the Receptor Activities
CR1 C3b, iC3b Erythrocytes, Clearance of immune C4b, iC4b phagocytic cells complexes
CR2 C3d B cells B cell coactivation
CR3 C3b, iC3b Phagocytic cells Immune complex binding, C4b, iC4b opsonophagocytosis, cell
adhesion
CR4 C3b, iC3b Phagocytic cells Immune complex binding, C4b, iC4b opsonophagocytosis, cell
adhesion
C3a/C4a R C3a, C4a Mast cells Degranulation leading to inflammatory mediator release
C5aR C5a Neutrophils ChemotaxisMast cells Degranulation and mediator
release
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2. The long, branching polysaccharide chains of bacterial surface lipopolysaccha-rides are thought to direct complement activation away from the outer lipidmembrane (Figure 1–3).
3. Pseudomonas aeruginosa produces a protease that cleaves C3b.
VI. Complement plays a central role in the pathogenesis of human disease.A. Serum complement levels can be markedly decreased in immune complex dis-
eases. 1. The circulating levels of C1, C2, C3, and C4 decline when immune complexes
containing IgM or IgG antibodies activate the classical pathway. a. Total complement activity is measured in complement hemolytic 50%
(CH50) units.b. Standard CH50 assays measure the activity of the classical pathway.
2. Regularly measuring total serum complement can be an effective means ofmonitoring the therapy of immune complex diseases.
B. C3b often deposits within tissues and induces inflammation (Chapter 13).C. Primary deficiencies of complement components cause inflammatory and infec-
tious diseases.1. Inherited deficiencies (generally autosomal recessive) of most of the individual
complement components have been described.
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IgβIgα
Bound C3d
CR2 CD19
CD81
IgM
Microbe
B cell activation
P P
P
P
P
PLyn
Fyn
BlkSyk
PI3-kinase
Figure 8–5. Signaling through the B cell coreceptor by binding C3d. Ig, im-munoglobulin; PI3-kinase, phosphatidylinositol-3-kinase.
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2. Deficiencies of the early classical and alternative pathways (eg, C1, C2, C4, andFactor B) are most often associated with an increased risk of bacterial infections.
3. The absence of C9 has only a minimum effect on infection rates.4. Patients with congenital deficiencies of C5, C6, C7, or C8 have an increased
risk of disseminated Neisseria infections (eg, meningitis).5. These observations would suggest that complement-dependent lysis of bacteria
is less important to the host than is its role in the chemotaxis and opsonophago-cytosis by neutrophils.
D. Paroxysmal nocturnal hemoglobinuria (PNH) is a condition characterized byepisodes of intravascular hemolysis and hemoglobinuria. 1. Patients’ erythrocytes are particularly sensitive to complement-mediated lysis.2. PNH patients lack the GPI-linked membrane proteins DAF and CD59.
a. Membrane C3 convertases are not well controlled, resulting in the deposi-tion of C3b (Table 8–2).
b. Assembly of the MAC is also not regulated at the cell membrane.E. Leukocyte adhesion defect type 1 (LAD-1) is a deficiency in the expression of
complement receptors CR3 and CR4.1. LAD-1 involves a mutation in the β2 integrin CD18 (Table 8–5).2. CD18 normally forms heterodimers with CD11a, CD11b, or CD11c.
a. The CD11a–CD18 dimer is the adhesion molecule LFA-1, which facilitatesneutrophil binding to endothelial cells and leukocyte emigration from theblood.
b. The CD11b–CD18 and CD11c–CD18 dimers are CR3 and CR4, respec-tively, which are adhesion and opsonic receptors on phagocytic cells.
3. LAD-1 patients suffer from recurrent pyogenic infections.
COMPLEMENT DEFICIENCIES AND AUTOIMMUNITY
• Patients with deficiencies of the early classical pathway components (eg, C2 and C4) have an increasedincidence of autoimmune disorders, especially lupus-like nephritis.
• This may reflect their inability to clear immune complexes that contain C3b generated by the classicalpathway.
• Conversely, patients with immune complex-mediated autoimmunity often show depressed levels ofC1, C2, C3, and C4 during acute attacks.
• C1qr2s2, C4b, C2a, and C3b are removed from the circulation when immune complexes are cleared byCR1-expressing erythrocytes.
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Table 8–5. Leukocyte adhesion defect type 1.a
CD18 Heterodimeric Partner Receptor Formed Receptor Ligands
CD11a LFA-1 ICAM-1
CD11b CR3 iC3b, iC4b
CD11c CR4 iC3b, iC4b
aLFA-1, lymphocyte function-associated antigen-1; ICAM-1, intercellular adhesion molecule 1.
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CLINICAL PROBLEMSA patient presents with recurrent joint pain and renal insufficiency, which is associatedwith immune complex deposition in these organs. It is determined that the patient doesnot clear IgG-containing immune complexes from the circulation at a normal rate.
1. A defect in which of the following complement receptors would most contribute to thislatter finding?
A. CR1
B. CR2
C. CR3
D. CR4
E. CR5
Mary is a 2-year-old child with a history of recurrent upper respiratory tract infections.She has normal serum Ig levels for her age, and her complete blood count (CBC) and testsfor neutrophil functions are normal. The total complement activity of her serum is normalin terms of supporting the lysis of antibody-coated erythrocytes. However, her serum com-plement is not activated by bacterial lipopolysaccharide (LPS).
2. Which of the following primary deficiencies of the complement system would be mostconsistent with these findings?
A. C2 deficiency
B. Factor D deficiency
C. MBL deficiency
D. C1 Inh deficiency
E. DAF deficiency
A 4-year-old child is referred to you with a diagnosis of leukocyte adhesion defect. She hasa history of recurrent bacterial infections, including pneumonias and skin abscesses. Radi-ology demonstrates granuloma-like lesions in her lung and liver. However, the data in thetable below suggest this condition has not been properly diagnosed.
3. Which element of the table is inconsistent with a diagnosis of LAD?
CD Marker Patient (%) Normal Range (%)
CD2 76 75–93CD3 75 60–85CD4 52 30–65CD8 26 20–52CD11a 65 62–85CD18 73 70–86CD19 12 7–17CD45 52 44–62
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A. CD2
B. CD3
C. CD19
D. CD11a
E. CD45
A pediatric patient presents with recurrent staphylococcal infections (pneumonias, sinusi-tis, and otitis media). Because many of her immune parameters are normal, you hypothe-size that she has a defect in her complement system.
4. For which of the following complement components or receptors would a deficiencyproduce this pattern of recurrent infections?
A. C2
B. C6
C. C8
D. CR1
E. CD59
A patient with the immune complex autoimmune disease systemic lupus erythematosus(SLE) is experiencing significant symptoms, including a worsening of her skin rash and ev-idence of impaired renal function.
5. If you were to test her serum complement levels during this acute phase of disease,which of the following would be most consistent with a worsening clinical course?
A. A decline in C9 levels
B. A decline in C3 and C4 levels
C. An increase in Factor P levels
D. An increase in C1 Inh levels
E. A decline in C7 levels
ANSWERS
1. The correct answer is A. Complement receptor CR1 is responsible for clearing immunecomplexes from the circulation by binding to C3b or iC3b. While CR3 and CR3 showthe same ligand specificity, the substantially larger number of CR1 receptors expressedby numerous erythrocytes in the blood make this receptor the primary vehicle of im-mune complex clearance.
2. The correct answer is B. Of the choices, only Factor D is unique to the alternativepathway of complement, which is activated by bacterial LPS. A deficiency of Factor Dprevents cleavage of Factor B, which is essential for producing the alternative pathwayC3 convertase.
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3. The correct answer is D. This patient appears to express normal levels of all of the CDmarkers shown here. This would not be expected of a patient with LAD type 1. Suchpatients lack CD18, which impairs the expression of CD11a, CD11b, and CD11c.
4. The correct answer is A. Of the components listed, only deficiencies in C2, C6, and C8result in an increased susceptibility to bacterial infections. With C6 and C8, thepathogens are members of the Neisseria genus and certain other gram-negative bacteria.Defects in early classical components, such as C2, result in recurrent pyogenic infec-tions by gram-positive bacteria, such as staphylococci.
5. The correct answer is B. Lupus is an autoimmune disease in which complement isactivated by IgG autoantibodies via the classical pathway. This can lead to an acute de-pletion in the early classical components, such as C1, C2, C3, and C4. The concentra-tions of the terminal components are affected much less.
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I. The development of a diverse, self-tolerant population of antigen-specificB cells is central to creating an adaptive immune system.A. The initial events of lymphopoiesis occur in the fetal liver and bone marrow and
do not require exposure to foreign antigens.1. Hematopoietic stem cells (HSC), which express CD34, are pluripotent and
can become any of the blood cell lineages (eg, erythroid, lymphoid, myeloid).2. Lineage commitment is determined by the hematopoietic inductive microen-
vironment, which includes stromal cell ligands and growth factors (Chapter12).
3. Interleukin-7 (IL-7) is an important growth factor for B and T lymphocytedevelopment.
4. Lymphocyte lineage commitment is indicated by the formation of the lym-phoid progenitor cell.
5. Commitment to the B lymphocyte lineage occurs at the progenitor B (pro-B)cell stage (Table 9–1). a. Most pro-B cells express CD19 as do all subsequent cells of the B cell lin-
eage.b. Recombination activating genes 1 and 2 (Rag1, Rag2) and terminal de-
oxynucleotidyltransferase (TdT) are expressed in preparation for im-munoglobulin (Ig) locus rearrangements.
c. The Ig H chain locus is rearranged by VDJ recombination, but H chainpolypeptides are not expressed.
6. The pro-B cell differentiates into a precursor-B (pre-B) cell, which expresses apre-B cell receptor (BCR).a. The pre-BCR consists of a membrane µ chain, an invariant surrogate L
chain, and Igα and Igβ polypeptides.b. Signaling through the pre-BCR induces allelic exclusion at the Ig H locus
and rearrangement of the κ locus.7. The pre-B cell differentiates into an immature B cell expressing an authentic
BCR.a. The BCR complex consists of membrane µ chains, κ or λ light chains, and
the Igα and Igβ polypeptides.b. Immature B cells exit the bone marrow and complete their differentiation
into mature B cells in the periphery.c. Most immature B cells die in the periphery unless they encounter antigen.
NC H A P T E R 9C H A P T E R 9
B CELL DIFFERENTIATION
AND FUNCTION
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8. Mature B cells express two forms of the BCR, membrane IgM and membraneIgD (Chapter 4).a. B-1 B cells are among the first peripheral B cells and are found predomi-
nantly in the peritoneal and pleural cavities. b. B-1 B cells produce natural antibodies thought to be induced by microbial
flora.c. B-1 B cells have a limited BCR repertoire.
(1) Most B-1 B cells produce low-affinity IgM antibodies specific for poly-saccharide antigens.
(2) The BCRs of B-1 B cells contain relatively conserved V regions.B. Selection occurs at several differentiation checkpoints and determines the periph-
eral B cell repertoire.1. Positive selection rescues bone marrow B cells from apoptosis (“death by ne-
glect”) (Table 9–2).a. Positive selection occurs at the pre-B and immature B cell stages.b. Selection requires signaling through the pre-BCR or BCR.c. The pre-BCR signals differentiation to the immature B cell stage and the
BCR promotes differentiation into mature B cells.d. Positive selection through the BCR probably involves low affinity binding
to self-ligands.
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Table 9–1. Stages of antigen-independent B cell differentiation.a
HSC Pro-B Pre-B Immature B Mature B
Igα, Igβ − + + + +
Rag1, 2 − + + + −
TdT − + + − −
Surrogate L chain − + + − −
Membrane µ chain − − + + +
Membrane δ chain − +
Membrane κ or λ chain − − − + +
Btk kinase − + + + +
Positive selection - − + + −
Negative selection − − − + −
aHSC, hematopoietic stem cells; Ig, immunoglobulin; Rag1, Rag2, recombination activating genes 1 and2; Tdt, terminal deoxynucleotidyltransferase; Btk, Bruton’s tyrosine kinase.
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X-LINKED AGAMMAGLOBULINEMIA
• X-linked agammaglobulinemia (XLA) is a congenital immune deficiency characterized by the lack ofperipheral B cells.
• Agammaglobulinemia becomes apparent only after maternal IgG disappears during the first year oflife.
• XLA patients have a mutation in the gene coding for Bruton’s tyrosine kinase (Btk).
• Btk is first required for signaling by the pre-BCR at the pre-B cell stage and mediates positive selection.
• A similar phenotype exists in patients with H locus deletions that prevent functional µ chain synthesisand pre-BCR expression.
2. Negative selection mediates removal of autoreactive B cell clones. a. Negative selection establishes self-tolerance. b. Negative selection occurs at the immature B cell stage and is mediated by
high-affinity BCR binding of self antigens.c. Negative selection can signal either apoptosis or anergy within B cells. d. Negative selection can stimulate BCR editing.
(1) The cell undergoes a second light chain locus rearrangement.
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CLINICALCORRELATION
Table 9–2. Positive and negative selection of developing B cells.a
Positive Selection Negative Selection
Stage of B cell Pre-B cell Immature B celldevelopment Immature B cell
Receptors Pre-BCR BCRBCR
Ligands Unknown Self antigens
Events triggered Allelic exclusion of Apoptosisby selection H locus BCR editing
Proliferation of pre-B Secondary κ locus cells rearrangement
κ locus rearrangement
Outcome Advancement to immature Elimination of B cell stage autoreactive B cell
clonesMonoclonal expression Replacement of
of µ chain autoreactive BCRsBCR expression
aBCR, B cell receptor.
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(2) The second rearrangement replaces the L chain of the self-reactive BCR.(3) The B cell undergoes another round of selection based on its new BCR.
II. In the periphery, antigen induces further differentiation of mature B cellsinto antibody-producing plasma cells and memory cells.A. Antigen enters the spleen, lymph nodes, and submucosal lymphoid follicles via
the blood, the lymph, or by transport across the mucosal epithelium, respectively.B. A single antigen-reactive B cell can give rise to thousands of daughter cells
through 10–-12 cell doublings.C. Activated B cells differentiate into sessile plasma cells that live for only a few days.
1. Differential RNA processing ensures that plasma cells synthesize secreted,rather than membrane, Igs (Chapter 4).
2. The progeny of a single B cell can synthesize up to 1012 antibody molecules.D. Antigen-specific, long-lived memory B cells also arise during B cell clonal expan-
sion in lymph node germinal centers.1. Follicular dendritic cells promote memory B cell development by retaining
antigens over long periods of time.2. Germinal center development is T cell dependent.3. Memory B cells undergo Ig isotype switching.4. Memory B cells mediate secondary responses characterized by the following:
a. A requirement for less antigen to induce the response.b. A shorter lag period before antibody is detected.c. Higher average affinity of the antibodies produced.d. The presence of additional Ig isotypes.
E. Affinity maturation accompanies memory B cell development. 1. Affinity maturation is an increase in the average affinity of an antibody re-
sponse over time.2. Affinity maturation is T cell dependent.3. Affinity maturation requires somatic hypermutation of Ig V region genes.
a. Proliferating B cell clones bear mutations in the complementarity determin-ing regions of their BCRs.
b. The average affinities of the antibodies these cells produce increase by 10- to100-fold.
c. Cells that express mutated, high-affinity BCRs are positively selected byantigen for additional cycles of proliferation.
III. Antigen-induced activation of B cells is mediated through the BCR,coreceptors, and cytokine receptors (Figure 9–1).A. The BCRs on mature naive B cells are membrane IgM and IgD.B. Memory B cells utilize membrane IgG, IgA, or IgE as their BCRs.C. Each of these BCRs signals through Igα and Igβ and intermediates that are simi-
lar to those used by the T cell receptor (TCR) (Chapter 6) (Table 9–3).D. Signaling is initiated by clustering of the BCR complex.
1. Polyvalent antigens with repeating identical determinants can activate B cellswithout coreceptor signals.
2. Most native protein antigens contain univalent epitopes that do not mediateBCR cross-linking.
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CD40
Ag
B7 CD28
MHC II
CD40
Cytokines
Activated B cells
CD40L (CD154)
Proliferating B cells
G1
G2
SM
G1
G2
SM
Binding Ag to BCR
Ag presentation by B cell
B cell-Th cell contact:• TCR-MHC class II• Coreceptors: B7, CD40
Cytokine receptorexpression
Cytokine signaling:IL-2, IL-4, IL-5, IL-6 Mitosis
S phase
G1 phase
G0 phaseB cell TH cell
Figure 9–1. Cooperative signaling for B cell activation by antigen. Ag, antigen;BCR, B cell receptor; TCR, T cell receptor; MHC, major histocompatibility com-plex; IL, interleukin.
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3. Igα and Igβ transmit BCR signals across the cell membrane.a. The cytoplasmic domains of Igα and Igβ contain immunotyrosine activa-
tion motifs (ITAM)(Figure 9–2). b. Src family kinases phosphorylate ITAM tyrosine residues.
4. The tyrosine kinase Syk is recruited to the phosphorylated ITAMs, becomesphosphorylated, and phosphorylates downstream adapter proteins (eg, BLNK)and latent kinases.a. Btk kinase is recruited to BLNK and activates phospholipase C� (PLC�).
(1) PLCγ hydrolyzes the membrane phospholipid phosphatidylinositol 4,5-biphosphate (PIP2) to form inositol triphosphate (IP3) and diacylglycerol(DAG).
(2) IP3 mobilizes intracellular Ca2+ and activates calcineurin.(3) Calcineurin activates the transcription factor NFAT by dephosphoryla-
tion.
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Table 9–3. Analogous components of the TCR and BCR signaling pathways.a
Signaling Event or Intermediate TCR Associated BCR Associated Effects
Clustering of receptors TCRαβ or TCRγδ BCR with Igα and Igβ Concentrate subsequent in the membrane with CD3 peptides signaling mediators
Phosphorylation Phosphorylation of Phosphorylation of Binding sites for of ITAMs CD3 ITAMs by Lck Igα and Igβ ITAMs downstream adaptor
by Src kinases proteins and kinases
Effector kinase ZAP-70 Syk Phosphorylates down-recruitment and stream adapters and activation kinases
Phospholipase PLCγ PLCγ PIP2 hydrolysisactivation
IP3 and DAG Ca2+ mobilization Ca2+ mobilization Calcineurin activationPKC activation PKC activation
Calcineurin activation NFAT NFAT Transcriptional activation dephosphorylation dephosphorylation through NFAT
PKC activation of IκB phosphorylation IκB phosphorylation Transcriptional activation IκB kinase through NFκB
Rac, Ras activation Fos/Jun Fos/Jun Transcriptional activation of MAP kinases phosphorylation phosphorylation through NFκB
aTCR, T cell receptor; BCR, B cell receptor; Ig, immunoglobulin; ITAM, immunotyrosine activation motif; ZAP-70, ζ-as-sociated protein-70 kDa; PLC, phospholipase C; PIP2, phosphatidylinositol 4,5-biphosphate; IP3, inositol triphosphate;DAG, diacylglycerol; PKC, protein kinase C; MAP, mitogen-activated protein.
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(4) Protein kinase C is activated by DAG, which indirectly induces thedegradation of I�B, the inhibitor of NF�B.
(5) The transcription factor NFκB is activated. b. The guanosine triphosphate/guanosine diphosphate (GTP/GDP) exchange
proteins Rac and Ras are activated.(1) Rac and Ras activate mitogen-activated protein (MAP) family kinases.(2) The MAP kinases activate the AP-1 family of transcription factors (eg,
Fos and Jun) by phosphorylation. 5. NFAT, NFκB, and AP-1 translocate to the nucleus and initiate gene transcrip-
tion by binding to their respective enhancers.6. The transcription of Ig, coreceptor, and cytokine receptor genes is initiated or
increased. E. Coreceptors enhance signals delivered through the BCR (Table 9–4).
1. Contact with T helper cells is required for coreceptor signaling.
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PLCγ activation GTP/GDP exchangeon Ras, Rac
Ras•GTP Rac•GTPIncreased cytosolic Ca2+ Diacylglycerol (DAG)
ERK, JNKCa2+-dependent enzymes
NFAT NFκB AP-1
PKC
P
PP P
P
BLNK
PLCγ
P
P
P
PBlk
Lyn
FynSyk
Grb2SOS
Btk
Figure 9–2. B cell receptor (BCR) signaling. PLC, phospholipase C; GTP,guanosine triphosphate; GDP, guanosine diphosphate; PKC, protein kinase C.
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a. The chemokine CCL7 mediates chemoattraction of B cells to the outer edgeof germinal centers where they bind Th cells.
b. Contact-dependent signaling is promoted by major histocompatibilitycomplex (MHC) class II, on B cells, which is bound by the TCR.
c. T cell contact-dependent signaling promotes B cell proliferation, increasesMHC class II expression, induces coreceptor, cytokine receptor, andchemokine receptor expression, promotes affinity maturation, and in-duces Ig class switching.
2. CD154 (CD40 ligand or CD40L) on CD4+ Th cells coactivates B cells bybinding to CD40.a. CD40 signals B cells to switch Ig class by H chain gene locus rearrange-
ment.b. Mutations in the CD154 gene can block T cell-induced Ig class switching in
B cells (hyper-IgM syndrome type 1).3. Complement activation during innate and adaptive immune responses can
generate the B cell coreceptor ligand C3d (Figure 8–5).a. C3d can covalently bind to antigens.b. C3d–antigen complexes cross-link the BCR with CR2, which is composed
of the CD19 and CD21 peptides.
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Table 9–4. Important receptors and coreceptors on B cells.a
Receptor or Coreceptor Ligand Biological Response
Pre-BCR Unknown Positive selection of pre-B cellsBCR Self antigens Positive and negative selection of
immature B cellsForeign antigens Activation of peripheral mature
B cells
CR2 C3d Coactivation of mature B cells Enhancement of BCR signaling
CD40 CD154 (CD40L) Coactivation of mature B cellsEnhancement of BCR signaling
IL-2R IL-2 Growth of activated B cells
IL-4R IL-4 Switching to IgE
IL-5R IL-5 Switching to IgA
IL-6R IL-6 Differentiation of cycling B cellsIncreased Ig synthesis
CCR7 CCL7 Chemotaxis of germinal center B cells
aBCR, B cell receptor; IL, interleukin; Ig, immunoglobulin.
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c. Src kinases associated with CR2 promote BCR signaling through phospho-rylation.
SWITCH RECOMBINASE DEFICIENCY
• Ig class switching involves a DNA recombination event mediated by the recombinase activation-in-duced cytidine deaminase (AID).
• Mutations in the AID gene have been described and result in impaired antigen-induced isotype switch-ing, somatic hypermutation in B cells, and affinity maturation of the antibody response.
• The resulting phenotype, designated hyper-IgM syndrome type 2, resembles the X-linked CD154 defi-ciency known as hyper-IgM syndrome type 1.
F. Cytokines produced by T helper cells promote B cell activation.1. Interleukin (IL)-2, IL-4, and IL-5 promote B cell proliferation.2. IL-6 enhances the differentiation of activated B cells into antibody-producing
plasma cells.3. IL-2, IL-4, and IL-6 promote antibody synthesis by activated B cells and
plasma cells.4. Several cytokines promote Ig class switching.
a. Switch cytokines promote specific switch recombinase interactions withspecific switch sites within the Ig H gene locus (Chapter 4).
b. IL-4 and IL-13 promote switching to IgE.c. Interferon (IFN)-γ promotes switching to IgG1 and IgG3. d. IL-5 and transforming growth factor-β (TGF-β) induce switching to IgA.
ANTICYTOKINE THERAPIES FOR CONTROLLING B CELL ACTIVATION
• Monoclonal antibodies capable of neutralizing cytokines or blocking their receptors have potential forthe treatment of allergic or neoplastic diseases involving B cells.
• For example, atopic allergies could theoretically be treated by blocking B cell switching to IgE synthesiswith anti-IL-4 or anti-IL-13.
• Another application undergoing clinical trials is the use of anti-IL-6 or anti-IL-6 receptor antibodies toinhibit the growth and Ig production of myeloma cells.
IV. Foreign polysaccharides, glycolipids, and nucleic acids induce antibodyproduction without the need for T cell help.A. These T-independent (TI) antigens contain repeating epitopes that cross-link
multiple BCRs on a single B cell.B. Some TI antigens (eg, bacterial LPS) also coactivate B cells through Toll-like re-
ceptors (Chapter 1). C. Some TI antigens [eg, lipopolysaccharide (LPS)] can activate complement and
coactivate B cells through CR2.D. Because TI antigens are not presented by antigen-presenting cells (APCs), they do
not activate CD4+ Th cells.E. The responses to TI antigens differ from responses to foreign proteins.
1. There is little Ig class switching in TI antibody responses; IgM and IgG2 anti-bodies predominate.
2. A limited repertoire of antibody-mediated effector functions results.
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3. Memory B cell populations are not formed and affinity maturation throughsomatic hypermutation does not occur.
4. High-titered antibody responses are not seen on secondary challenge.
SELECTIVE IGG2 DEFICIENCY
• IgG2 is a common subclass of antibody produced in response to T-independent antigens in humans.
• Antibody responses to protein antigens are predominantly of the IgG1 subclass.
• Children with selective IgG2 subclass deficiency have difficulty clearing bacteria that express polysac-charide capsules (eg, Streptococcus pneumoniae and Haemophilus influenzae).
• The increased survival of encapsulated bacteria in IgG2-deficient patients suggests that other(sub)classes of Igs do not provide sufficient host defense against these organisms.
V. Antibody responses at mucosal surfaces are mediated by a specialized setof B cells that synthesizes IgA antibodies.A. Most of the IgA in the body is synthesized in the small intestine.B. IgA-secreting plasma cells are most abundant within the lamina propria of the
submucosum and produce 2 g of Ig per day.C. The secretory form of IgA is the central mediator of mucosal humoral immunity.
1. Secretory IgA is dimeric and contains J chain and secretory component(SC)(Chapter 3).a. The α, κ, λ, and J chains of dimeric IgA are produced by mucosal B cells.b. Secretory component is synthesized by the intestinal epithelial cell.
2. Secretory component mediates transepithelial transport of IgA.a. On the basolateral surface of epithelial cells, a precursor of SC called poly-
Ig receptor is expressed (Figure 9–3).b. The poly-Ig receptor binds the polymeric Igs (IgA and IgM).c. The loaded receptor is internalized into endosomes, which are translocated
to the apical cell surface.
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Lamina propria Lamina propria Lumen
IgA-producingplasma cell
Dimeric IgA Endocytosed complexof IgA and Poly-Igreceptor
J chain Poly-Ig receptorwith bound IgA Secretory IgA
Proteolyticcleavage
Mucosal epithelial cell
Figure 9–3. Transport of dimeric immunoglobulin A (IgA) by poly-Ig receptor.
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d. Proteolytic cleavage of the poly-Ig receptor releases secretory componentwith its polymeric Ig attached.
D. At the mucosal surface, secretory IgA neutralizes toxins and allergens and preventsmicrobial entry.
SELECTIVE IGA DEFICIENCY
• Selective IgA antibody deficiency is the most common antibody deficiency in humans with frequenciesas high as 1:333 reported in some populations.
• This deficiency is characterized by recurrent bacterial and viral infections originating at mucosal sur-faces (respiratory, gastrointestinal, and genitourinary tract infections).
• Increased incidences of food allergies, autoimmunity, and certain types of cancers have also been re-ported in these patients.
• However, half of all persons with this deficiency are asymptomatic.
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SecretoryIgA
Antigen
MLN
IgA
IgA
IgA
IgA
IgA
IgA
Thoracic duct
Blood stream
DimericIgA
MonomericIgA
B cellPlasmacell
M cell
PPPPPP
IgA
Figure 9–4. Induction of a mucosal immunoglobulin A (IgA) antibody response. M,microfold; PP, Peyer’s patch; MLN, mesenteric lymph node.
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• The absence of increased rates of infection in the unaffected subset of IgA-deficient individuals proba-bly reflects the translocation of secretory IgM by the poly-Ig receptor.
E. Mucosal IgA antibody responses are initially induced within submucosal Peyer’spatches of the small intestine (Figure 9–4). 1. The epithelium overlying the patch is composed of specialized nonvillous ep-
ithelial cells, called M cells, which efficiently transport antigens to lymphoidcells within the patch.
2. Peyer’s patch Th cells produce IL-5 and TGF-β, two IgA switch cytokines.3. B cells activated in the Peyer’s patches migrate via draining lymph nodes into
the lymph and blood.4. Circulating IgA-expressing B cells then seed the intestine and other mucosal-
associated lymphoid tissues (MALT). 5. By this process, the recognition of enteric antigens leads to the production and
transport of secretory IgA at multiple mucosal tissue sites.
MUCOSAL AND PARENTERAL VACCINES
• In the 1950s two competing vaccines were produced against the polio virus.
• The parenteral (Salk) vaccine was injected by the intramuscular route and induced IgG antibody pro-duction.
• These antibodies prevented disease by neutralizing virus particles in transit from the gastrointestinaltract to the nervous tissues.
• The Sabin vaccine was an inactivated virus, and oral immunization resulted in secretory IgA responsesin the gut-associated lymphoid tissues.
• Secretory IgA antibodies prevented viral attachment and entry into intestinal epithelial cells.
• Current recommendations are for children to receive the parenteral vaccine at 2, 4, and 6 months ofage (www.cdc.gov/nip/recs/child-schedule.PDF).
CLINICAL PROBLEMSA patient is shown to have a mutation in his Btk tyrosine kinase gene.
1. Which of the following stages of lymphocyte differentiation is blocked in this patient?
A. Differentiation of mature B cells into plasma cells
B. Generation of memory B cells
C. Differentiation of pre-B cells into immature B cells
D. Negative selection of mature B cells
E. Activation of mature B cells
A patient presents with recurrent bacterial infections and is found to have low serum levelsof IgA and IgG1, but elevated concentrations of serum IgM. Flow cytometry of his lymphnode cells reveals an absence of CD154.
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2. In which of the following areas of the lymph node would this cell surface marker nor-mally be found?
A. Medullary cords
B. Diffuse cortex
C. Germinal centers
D. High endothelial cells of the venules
E. Subcapsular sinuses
Lymphocytes from an immunodeficient patient are found to lack mRNA for AID.
3. Which of the following lymphocyte subsets would be expected to be absent in this pa-tient?
A. Lymph node B cells expressing membrane IgG
B. CD4+ T lymphocytes in the blood
C. Natural killer (NK) cells in the spleen
D. All lymphocytes in peripheral lymphoid tissues
E. CD19+ B cells in the bone marrow
You have a patient with recurrent infections, but normal T cell function.
4. Which of the following laboratory tests would help you determine if this immune defi-ciency is due to an absence of B cells?
A. Radioimmunoassay
B. Flow cytometry
C. Enzyme-linked immunosorbent assay (ELISA)
D. Immunofixation
E. Coombs test
A lymph node biopsy stained with hematoxylin and eosin shows numerous germinal cen-ters in the superficial cortex.
5. Which of the following best describes the source of this biopsy tissue?
A. A patient who lacks CD154
B. A patient who lacks Rag1
C. A patient who has been immunized repeatedly with a protein vaccine
D. A patient who has been immunized repeatedly with streptococcal polysaccha-rides
E. A newborn
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ANSWERS
1. The correct answer is C. Whereas the Btk kinase is used for both BCR and pre-BCRsignaling, an absence of Btk is manifest first in pre-B cells. The mutation causes defec-tive positive selection of pre-B cells and apoptotic death. There are no peripheral im-mature or mature B cells in Btk-deficient individuals, a condition known as XLA.
2. The correct answer is B. CD154 would normally be found on Th cells in the diffuse ordeep cortex. Its absence is indicative of hyper-IgM syndrome type 1.
3. The correct answer is A. The switch recombinase AID is normally expressed in B cellsthat are undergoing Ig isotype switching.
4. The correct answer is B. Only flow cytometry would be able to demonstrate the ab-sence of B cells. The other techniques would not distinguish between an absence of Bcells and the inability of those cells to secrete antibody.
5. The correct answer is C. Germinal center development is antigen, Th cell, and CD40dependent. The antigen must be a T-dependent antigen, such as a protein. Polysaccha-ride antigens do not induce germinal center formation, and newborns have generallynot encountered protein antigens in utero that elicit this type of response.
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I. The development of T lymphocytes is similar to that of B cells, althoughunique events occur in the inductive environment of the thymus.A. Thymic maturation does not require exposure to foreign antigen. B. Like B cells, T cells are derived from pluripotent hematopoietic stem cells in the
fetal liver and bone marrow, which differentiate into common lymphoid progen-itor cells and progenitor T (pro-T) cells (Table 10–1).
C. The pro-T cell begins its migration from the bone marrow to the thymus duringthe first trimester of human pregnancy.
D. In the thymus the cells are called thymocytes and undergo considerable cell divi-sion and apoptotic death.1. Differentiation is induced by stromal cells and growth factors.
a. Epithelial cells, macrophages, and dendritic cells provide both contact-dependent and secreted signals.
b. Interleukin (IL)-7 is a key growth-promoting factor for thymocytes. c. Major histocompatibility complex (MHC) molecules promote thymocyte
growth and apoptosis. 2. Thymocytes are subjected to both positive and negative selection based on the
specificity of their T cell receptors (TCRs).E. The production of mature T cells occurs throughout life, but the thymus becomes
less important as it atrophies with age.
THE BUBBLE BOY
• In the 1976 movie “Boy in a Bubble,” a child with a severe immunodeficiency avoided life-threateninginfections by living in a pathogen-free plastic tent.
• A number of molecular defects can cause this condition, known as severe combined immune defi-ciency.
• These include mutations in the genes for the Rag recombinases, adenosine deaminase, and the γ chainof the IL-2 receptor (Chapter 16).
• The microbial pathogens that establish early opportunistic infections in these children include intracel-lular fungi, viruses, and bacteria.
• While B cell differentiation can also be directly or indirectly affected (depending on the mutation), ma-ternal IgG provides immune protection early in life.
• Hematopoietic stem cell transplantation provides the only practical cure.
NC H A P T E R 1 0C H A P T E R 1 0
T CELL DIFFERENTIATION
AND FUNCTION
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II. Thymocyte differentiation is accompanied by the generation of the TCRrepertoire and the establishment of functional cell subsets.A. Four important events in the development of the T cell lineage occur.
1. TCRαβ and TCRγδ genes are rearranged by recombination (Chapter 6) andare expressed.
2. The MHC restriction specificity of the T cell lineage is established.3. Thymocytes with autoreactive TCRs are eliminated.4. Two major functional T cell subsets (CD4+ and CD8+) are generated.
B. Clonal proliferation, apoptotic death, and differential gene expression accompanythymocyte differentiation.1. Pro-T cells migrate to the superficial cortex and become part of the pool of
double-negative (CD4–CD8–) thymocytes (Table 10–1 and Table 10–2).a. Pro-T cells begin to express recombination activating genes 1 and 2 (Rag1,
Rag2) and terminal deoxynucleotidyltransferase (TdT) in preparation forTCRβ locus rearrangements.
b. In most pro-T cells, the β locus undergoes D–J rearrangement.c. Approximately 5% of the descendants of these cells will express γδ TCRs
and the remainder will become TCRαβ+.2. Pro-T cells then differentiate into pre-T cells, in which V–DJβ joining occurs
and a β chain polypeptide is expressed.
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Table 10–1. Stages of T cell differentiation.a
HSC Pro-T Pre-T Double Single Naive Mature Positive Positive T Cell
Rag − + − + − −
TdT − + − − − −
TCR DNA Germline Germline Rearranged Rearranged Rearranged Rearranged ββ chain β and α chain β and α chain and α chain
TCR None None Pre-TCR TCR TCR TCR
CD3 − − + + + +
Surface markers − − − CD4+8+ CD4+ or CD8+ CD4+ or CD8+
Anatomic site Bone Thymus Thymus Thymus Thymus Peripherymarrow
Response None None Positive Positive and Negative Activationto TCR selection negative selectionligation selection
aTdt, terminal deoxynucleotidyltransferase.
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a. A pre-TCR is expressed that contains a β chain plus a pre-T� chain andCD3 peptides.
b. Activation of pre-T cells through the pre-TCR stimulates cell proliferation,β locus allelic exclusion, α locus rearrangement, and the expression of CD4and CD8.
3. Double positive thymocytes express TCRαβ with CD3 peptides.a. Rag1,2 are expressed for a second time to facilitate rearrangement of the α
locus.b. TCRαβ binding to MHC molecules signals further maturation.
(1) Rag1,2 genes become silent.(2) Positive and negative selection occurs as the cells transition to a single
positive (CD4+8– or CD4–8+) state.4. Single positive cells emerge from the thymus and undergo further maturation
in the peripheral lymphoid tissues. 5. The maturation of thymocytes can be monitored by polychromatic flow cy-
tometry (Figure 10–1).a. Using antibodies to CD4 and CD8, each with a different fluorochrome,
four cell subsets can be identified. (1) Double negative (CD4–CD8–) cells are the pro-T and pre-T cells.(2) Double positive (CD4+CD8+) cells express TCRαβ or TCRγδ and are
positively and negatively selected based on their TCR specificities. (3) Single positive (CD4+CD8– or CD4–CD8+) cells are fairly mature and
ready to exit the thymus.b. A similar analysis of peripheral T cells would identify only the two single-
positive subsets.
SIGNIFICANCE OF ORAL THRUSH IN INFANTS
• A cardinal clinical sign of defective cellular immunity in a neonate is the appearance of mucocuta-neous candidiasis or thrush.
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Table 10–2. The major subsets of the TCRαβ lineage of thymocytes.a
Thymocyte Subset Surface Phenotype Major Events or Properties
Double negative Pro-T cell CD4–CD8–TCR– TdT+Rag1,2+; D-Jβ rearrangementPre-T cell CD4–CD8–TCR–CD3+pre-TCR+ Rag1,2+; V-DJβ rearrangement
Double positive CD4+CD8+CD3+TCRαβ+ V-Jα rearrangementPositive and negative selection
Single positive CD4+ CD4+CD8–CD3+TCRαβ+ Negative selectionCD8+ CD4–CD8+CD3+TCRαβ+ Negative selection
aTCR, T cell receptor.
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• Oral thrush is uncommon in immunocompetent individuals.
• This painful condition is caused by a superficial infection by the opportunistic yeast Candida albicans,which is normal flora in the oral cavity.
• The most frequent immune deficiency causing neonatal thrush is AIDS.
• However, any cellular immune deficiency, including severe combined immunodeficiency (SCID), selec-tive T cell deficiencies (eg, DiGeorge syndrome, CD3 mutations), and MHC deficiencies, can increase therisk of thrush.
III. Host MHC molecules determine the specificities of the TCRs that survivethymic selection.A. The potential repertoire of TCRαβ and TCRγδ receptors is determined by the
quasirandom recombination events within the DNA that codes for TCR V re-gions (Chapter 6).
B. The utilized repertoire of TCRs results from the selection of receptors with theability to recognize foreign peptides presented by the MHC of the host.
C. The affinity with which thymocyte TCRs bind MHC molecules in the thymusdetermines whether positive or negative selection will occur. 1. In the absence of binding, thymocytes undergo death by neglect.2. Low-affinity TCR–MHC interactions trigger positive selection.3. High-affinity TCR binding to MHC signals negative selection.
D. Positive selection promotes the development of thymocytes with TCRs specificfor foreign peptides plus the host’s own MHC molecules.1. Cells bearing TCRs specific for non-self MHC (ie, that of another individual)
die by neglect.2. Positive selection occurs at the double-positive thymocyte stage and induces
differentiation to the single-positive phenotype. a. Double-positive thymocytes with TCRs that bind to self MHC class I mole-
cules are induced to become CD4–CD8+.
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CD8
100 101 102 103 104
CD4
100
101
104
103
102
2%
5% 83%
10%
Figure 10–1. Identification of the major subsets of thymocytes by flow cytometry.(Courtesy of Thomas Yankee, University of Kansas Medical Center)
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b. Double positive thymocytes with TCRs that bind to MHC class II mole-cules become CD4+CD8– single positive.
c. Clones that express TCRs specific for nonhost MHC class I or II are notpositively selected and die by default.
d. The majority of developing thymocytes are not positively selected and un-dergo apoptosis.
MHC DEFICIENCIES PREVENT POSITIVE SELECTION
• Two important groups of immune deficiency diseases result from inefficient positive selection of thy-mocytes.
• Bare lymphocyte syndrome (BLS) type 1 and type 2 (Chapter 7) are congenital deficiencies in whichMHC class I and class II molecules, respectively, are not expressed.
• The absence of MHC molecules precludes positive selection of double positive thymocytes and the cor-responding T cell subset fails to develop.
• For example, BLS type 2 patients are lymphopenic, because CD4+ T cells, which normally constitute themajority of T cells in the blood, do not develop.
• The differential diagnosis of BLS type 2 requires exclusion of HIV-1 infection, which is a much morecommon cause of decreased CD4:CD8 ratios (Chapter 15).
E. Negative selection eliminates potentially harmful thymocyte clones that bearhigh affinity receptors for self peptides plus self MHC molecules. 1. Negative selection establishes central tolerance to self antigens (Chapter 16).2. Negative selection occurs at the double positive-to-single positive transition.3. Both MHC class I and class II can signal negative selection.4. Coreceptor signaling through CD4 and CD8 promotes negative selection.5. The death signal during negative selection is delivered through Fas–Fas ligand
interactions between thymocytes and stromal cells of the thymus.F. Four potential outcomes result from the binding of peptide–MHC complexes by
TCRs.1. Thymocyte clones are induced to proliferate and differentiate (positive selec-
tion).2. Thymocyte clones undergo apoptosis (negative selection).3. Peripheral T cells proliferate and differentiate in response to foreign antigens.4. Peripheral T cells can become anergic (peripheral tolerance) if coreceptor sig-
naling is lacking (Chapter 16).
DEFECTIVE THYMIC APOPTOSIS
• Apoptotic death regulates thymocyte selection and T cell activation in the periphery.
• Autoimmune lymphoproliferative syndrome (ALPS) (also known as Canale–Smith syndrome) is adefect in the apoptosis of activated T cells.
• In most patients a mutation exists in the gene coding for Fas (CD95).
• Patients present with greatly enlarged lymph nodes, splenamegaly, and autoimmunity (eg, Coombs-positive hemolytic anemias).
• Affected individuals also show lymphocytosis and an elevated number of double negative(TCRαβ+CD4–CD8–) T cells in the blood.
• Similar phenotypes occur with patients bearing mutations in Fas ligand or certain caspase genes.
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IV. Cell surface adhesion molecules, coreceptors, and cytokine receptorsregulate T cell activation in the periphery. A. Cell adhesion molecules promote T cell homing to specific tissues by binding to
ligands on vascular endothelial cells and matrix proteins.1. T cells express integrins, such as lymphocyte function-associated antigen-1
(LFA-1), that mediate lymphocyte homing to sites of infection and inflamma-tion.
2. Specialized integrins direct T cells to mucosal lymphoid tissues. 3. Integrins increase the avidity of binding between T cells and their antigen-pre-
senting cells.4. Integrins promote binding between cytotoxic T cells and their target cells.
B. Coreceptors are induced and recruited to the immunological synapse that formsbetween a T cell and its antigen-presenting cell.1. The cell surface expression of coreceptors and their ligands is often regulated to
avoid the unwanted activation of resting T cells.2. Receptor clustering brings coreceptors in proximity to TCRs. 3. Receptor clustering promotes synergy between intracellular signaling pathways. 4. CD4 and CD8 are coreceptors that bind to nonpolymorphic residues of MHC
class II and class I molecules, respectively.a. The T cell-specific kinase Lck is associated with CD4 and CD8 in the
membrane. b. Lck phosphorylates immunotyrosine activation motif (ITAM) residues on
CD3 peptides.c. Thymocytes lacking Lck are not positively selected at the double-positive
stage.5. CD28 and cytotoxic T lymphocyte-associated protein 4 (CTLA-4)
(CD152) on T cells modify TCR signaling.a. The costimulatory ligands for these coreceptors are members of the B7
family and are expressed on antigen-presenting cells.b. Ligation of CD28 on naive T cells by B7 induces phosphatidylinositol-3-
kinase activation. c. Stimulation of T cells through CD28 activates NFκB.d. CTLA-4 is expressed on activated T cells and mediates negative signaling
when B7 is bound. 6. CD154 is a coreceptor for CD4+ Th cells.
C. Cytokine receptors augment or inhibit T cell responses to antigen. 1. The expression of cytokine receptors is often induced by antigen and corecep-
tor stimulation.2. IL-2 is a growth factor for activated CD4+ and CD8+ T cells.3. IL-4 promotes the differentiation of the Th2 subset from naive, antigen-
stimulated CD4+ T cells.4. Interferon (IFN)-� promotes the differentiation of the Th1 subset of T cells.5. IL-10 and transforming growth factor (TGF-�) inhibit the activation of Th1
cells.6. IFN-� inhibits the activation of Th2 cells.
D. Different types of costimulatory and cytokine signals are derived from differenttypes of antigen-presenting cells (Table 10–3).
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1. Dendritic cells are particularly effective at activating naive CD4+ T cells, be-cause they express B7 and MHC class II constitutively.
2. B cells have the advantage of being able to capture limited quantities of antigenthrough their BCR, which aids in activating memory T cells with high-affinityTCRs.
3. Macrophages can phagocytize particulate antigens and present their epitopesto T cells.
V. The activation of mature T cells by antigen in the periphery leads toclonal expansion and differentiation into effector and memory cellsubsets. A. The frequency of T cells specific for a given antigen changes during an immune
response.1. Clonal frequencies among resting naive T cells is approximately 10–6. 2. The frequency of antigen-specific T cells increases to 10–2 at the peak of the ex-
pansion phase.3. Memory cells for a given antigen exist at a frequency of 10–4.
B. CD4+ helper T cells (Th cells) can be subdivided into two subsets (Figure 6–5).1. Th1 cells mediate cellular immunity to intracellular microbial pathogens by
the secretion of cytokines [eg, IL-2, IFN-γ, and tumor necrosis factor (TNF)-α] that promote T cell growth and activate macrophages and neutrophils.
2. Th2 cells promote humoral immunity to extracellular microbial pathogens byproducing cytokines (IL-4, IL-5, and IL-13) that activate B cells.
C. Memory T cells divide at a low rate and recirculate for decades. 1. The chemokine receptor CCR7 and certain adhesion molecules facilitate mem-
ory T cell migration into lymph nodes. 2. The antigen-presenting cell (APC) signals required to activate a memory T cell
with antigen are different than those required by naive T cells (Table 10–2). 3. Memory T cells become a greater proportion of the T cell pool with age.
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Table 10–3. Differences between APCs related to T cell activation.a
Property Dendritic Cell B Cell Macrophage
Antigen uptake Active endocytosis BCR-mediated Endocytosis and endocytosis phagocytosis
MHC class II Constitutive Constitutive Inducible expression
Costimulatory Constitutive B7 Inducible B7 Inducible B7ligand expression
T cells activated Naive, effector and Effector and Effector and memorymemory memory
aAPC, antigen-presenting cells; BCR, B cell receptor.
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D. Regulatory T (Treg) cells inhibit immune responses (Chapter 11). 1. Treg cells are most often CD4+ and express CD25, the α chain of the high-
affinity IL-2 receptor.2. Treg cells produce the inhibitory cytokines IL-10 and TGF-�.3. Treg cells contribute to the maintenance of self tolerance (Chapter 16).
E. Several subsets of T cells and related lymphocytes are cytotoxic (Table 10–4). 1. Cytotoxic T lymphocytes (CTL) are induced by antigen, terminally differen-
tiated and short lived. a. Most CTL are CD8+ and MHC class I restricted.b. Cytotoxic CD4+ cells exist, but are MHC class II restricted.c. Both TCRαβ and TCRγδ T cells can be cytotoxic.d. Cytotoxicity is mediated by the granzyme–perforin pathway, the Fas–Fas
ligand pathway, and the TNF receptor pathway (Chapter 6).2. The �� T cell subset shows specificity for pathogens associated with epithelial
surfaces.a. γδ T cells are intraepithelial lymphocytes that accumulate in the skin,
small intestine, lung, and genitourinary tract.b. Most TCRγδ+ cells do not express CD4 or CD8.c. TCRγδ is specific for nonpeptides, including glycolipids that represent
pathogen-associated molecular patterns.d. TCRγδ is not MHC restricted.
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Table 10–4. A comparison of conventional T cells, γδ T cells, NKT cells, and NK cells.a
Conventional Property T Cell γδ T Cell NKT Cell NK Cell
Tissue location Spleen, lymph Intraepithelial Thymus, liver, Liver > spleennodes, lymphoid spleenfollicles
Receptor type TCRαβ + CD3 TCRγδ + CD3 Invariant TCRαβ Activating+ CD3 FcγR
NKG2DInhibitory
KIRLectins
Receptor Peptide + MHC Microbial Microbial Activating specificity class I or class II glycolipids glycolipids IgG antibody
Stress-induced Stress-induced host ligands host ligands
There are two recep- Inhibitory tor types and two HLA-A,B,Creceptor specificities: activating and inhibitory
aNKT, natural killer T; TCR, T cell receptor; MHC, major histocompatibility complex; KIR, killer in-hibitory receptor; IgG, immunoglobulin G.
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e. Signaling through TCR�� is similar to that of TCRαβ. f. γδ T cells can be cytotoxic or cytokine producing.
3. Natural killer T (NKT) cells express both TCRs and NK cell markers.a. The invariant TCRαβ of NKT cells is restricted by CD1 and specific for
microbial glycolipids.b. NKT cells respond rapidly to antigen and produce IL-4 and IFN-γ.
F. Although not thymus derived, NK cells share a number of properties with T cellsand NKT cells.1. NK cells recognize host cells infected with intracellular microbial pathogens
using unique receptors.a. NK cell inhibitory receptors recognize MHC class I molecules and deliver
signals that are dominant over NK cell-activating receptor signals. b. NK cell-activating receptors recognize host cell ligands that are present on
infected or stressed cells. c. When host cells fail to express MHC class I (as during virus infections), the
inhibitory signal is lost and the NK cell becomes activated. d. Activating receptors signal through their ITAMs and inhibitory receptors
utilize immunotyrosine inhibitory motifs (ITIMs) to transmit intracellularsignals.
e. The functions of NK cells are promoted by cytokines.2. NK cells mediate innate immunity by producing cytokines (eg, IFN-γ) and
killing infected target cells without the need for clonal expansion.3. Important coactivating signals for NK cells include IL-12 and IFN-α/β.
CHEDIAK–HIGASHI SYNDROME
• Chediak–Higashi Syndrome (CHS) is a rare autosomal recessive condition characterized by recurrentinfections and poor NK cell activity.
• The genetic defect resides in the gene for lysosomal trafficking regulator (LYST) and causes a fusionof cytoplasmic granules in NK cells, neutrophils, monocytes, and other granule-containing cells.
• CHS NK cells bind normally to their target cells, but killing is absent.
• The immune deficiencies of CHS patients are probably more related to defective neutrophil functionthan impaired NK cell activity.
CLINICAL PROBLEMSYou have a patient with enlarged lymph nodes, splenamegaly, and anemia. During an im-munological work-up you find that the patient has a slight lymphocytosis. You performmulticolor flow cytometry after staining the patient’s blood lymphocytes with antibodiesto CD3, CD4, and CD8. Shown below are CD3+ blood lymphocytes stained for CD4 (x-axis) and CD8 (y-axis) expression.
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1. Which of the patterns shown above would suggest an apoptosis defect is responsible forthis patient’s disease?
A. A
B. B
C. C
D. D
E. E
A patient with BLS type 1 presents with a herpes virus infection. His blood lymphocytesare found to kill autologous virus-infected target cells rapidly in vitro.
2. Which of the following cell types is probably mediating this killing?
A. CD8+ T cells
B. γδ T cells
C. Macrophages
D. NK cells
E. B cells
You are a member of a cardiac transplantation team in a medical school and meet withsecond-year medical students to explain the surgical procedure and posttransplantationtherapy. One of the drugs you review is cyclosporine.
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A B
D E
CD8
APC-
Cy7
101 102 103 104 105
CD4 FITC
102
105
104
103
101
C
102 103 104 105
102
105
104
103
102 103 104 105
102
105
104
103
102 103 104 105
102
105
104
103
102 103 104 105
CD3+ T cells
CD8
APC-
Cy7
101
CD4 FITC
101
CD3+ T cells
CD8
APC-
Cy7
101
CD4 FITC
101
CD3+ T cells
CD8
APC-
Cy7
101
CD4 FITC
101
CD3+ T cells
CD8
APC-
Cy7
101
CD4 FITC
101
CD3+ T cells
102
105
104
103
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3. Which of the following would be a reasonable summary of its immunosuppressive ef-fect?
A. The drug kills dividing T and B cells in metaphase.
B. The drug inhibits antigen processing by dendritic cells.
C. The drug inhibits IL-2 gene transcription in T cells.
D. The drug blocks NK cell recognition of foreign HLA antigens.
E. The drug inhibits HLA class I expression by cardiac muscle cells.
Mutations in either Rag1 or Rag2 cause severe immunodeficiencies in human beings.
4. Which of the following cell types would show normal numbers in a patient with aRag1 deficiency?
A. CD3+ cells with a CD4 coreceptor
B. CD19+ cells
C. Single positive thymocytes
D. Lymphocytes with a coreceptor specific for C3d
E. Cells with an inhibitory receptor specific for MHC class I
Johnny is an 8-month-old child with recurrent viral and fungal infections. His blood lym-phocytes can bind IL-2, and his macrophages can bind IFN-γ in vitro. It has been deter-mined that his parents are both heterozygous for a mutation in the ZAP-70 gene knownto disrupt the activity of this kinase.
5. Assuming Johnny has inherited this mutation from both parents, which of his cellsshould be normal?A. Monocytes and macrophages
B. TCRαβ T lymphocytes
C. TCRγδ T lymphocytes
D. NK cells
E. NKT cells
ANSWERS
1. The correct answer is A. This pattern is abnormal in the sense that the blood containslarge numbers of double negative T lymphocytes (CD3+CD4–CD8–). Normally, dou-ble negative CD3+ cells are found only in the thymus (panel E). This finding suggestsaltered thymic selection and peripheral homeostasis of T cell subsets secondary to de-fective apoptosis induced by the Fas–Fas ligand system (ie, autoimmune lymphoprolif-erative syndrome). The normal pattern for blood CD3+ cells is shown in panel D.
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2. The correct answer is D. NK cells recognize virus-infected and neoplastic cells that lackMHC class I, which is characteristic of cells from patients with BLS type 1.
3. The correct answer is C. Cyclosporine inhibits the Ca2+/calmodulin-dependent phos-phatase calcineurin, which leads to decreased TCR-initiated dephosphorylation of thelatent transcription factor NFAT. With diminished NFAT activation, IL-2 and IL-4gene transcription is decreased, which has a general immunosuppressive effect on acti-vated T cells.
4. The correct answer is E. T–B–NK+ SCID is caused by Rag recombinase deficiency. Thepatients have normal numbers of NK cells, which bear inhibitory receptors for MHCclass I molecules.
5. The correct answer is A. All of the lymphocyte subsets listed use ZAP-70 as a signalingintermediate for receptor-induced cell activation.
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I. The immune response is regulated at the level of antigen recognition bymechanisms designed to distinguish self from nonself.A. The innate immune system recognizes pathogen-associated molecular patterns
that are not seen on host tissues.B. The adaptive immune system recognizes nonself epitopes using T and B cell re-
ceptor repertoires that have been selected for their specificity during lymphocytedifferentiation.
C. Both systems are imperfect, and immune responses to self components can ariseeven in healthy individuals (Chapter 16).1. Toll-like receptors recognize self components derived from damaged tissues
(eg, heat shock proteins).2. Antibody production against self antigens occurs frequently without any ad-
verse effect.
II. Antigen-presenting cells (APCs) control the induction of adaptive immuneresponses.A. The constellation of major histocompatibility complex (MHC) molecules ex-
pressed by an APC determines the peptides it can present.B. Coreceptor signals derived from APCs influence the type of immune response
induced. 1. Whereas mature dendritic cells (DC) activate CD4+ Th cells, immature DC ac-
tivate CD4+ Treg cells.2. CD28 binding of B7 molecules induces Th cell activation, whereas cytotoxic T
lymphocyte-associated protein 4 (CTLA-4) binding of B7 molecules inhibitsTh cell activation.
C. Cytokines influence APC functions and lymphocyte activation.1. Interferon (IFN)-γ and tumor necrosis factor (TNF)-α increase MHC class II
expression and APC function. 2. Macrophage- and DC-derived interleukin (IL)-12 promotes Th1 cell activation.3. IL-4 produced by T cells and mast cells promotes Th2 cell differentiation.
III. When an immune response does occur, its duration is limited, and theimmune system returns to a basal homeostatic state. A. As antigen is cleared from the body, lymphocyte activation subsides.
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B. Antigen-activated lymphocytes undergo activation-induced cell death.1. Activated T lymphocytes express both Fas and Fas ligand, which signals apop-
totic death. a. The cytoplamic domains of Fas contain death domains that bind adapter
proteins, recruit and activate caspases, and trigger apoptosis.b. Fas deficiency in humans causes autoimmune lymphoproliferative syn-
drome (ALPS) (Chapter 10), the failure of activated T cells to undergoapoptosis.
2. Oxidant production by activated cells initiates cell death through the endoge-nous apoptosis pathway.
C. Effector lymphocytes, neutrophils, and macrophages are relatively short lived. D. Memory B and T cells show only low levels of proliferation. E. Antibodies regulate immune responses to their antigens.
1. Maternal antibodies that cross the placenta can interfere with the immuniza-tion of the newborn in the first few months of life.
2. Complement-activating antibodies enhance B cell activation through the CR2coreceptor (Chapter 9).
3. Immune complexes containing immunoglobulin G (IgG) can also inhibit Bcell activation (Figure 11–1).a. IgG antibody–antigen complexes can simultaneously bind to the Fc� recep-
tor IIB (Fc�RIIB) and BCR. b. BCR cross-linking to FcγRIIB blocks B cell receptor (BCR) signaling.
(1) The cytoplasmic tail of FcγRIIB contains immunotyrosine inhibitorymotifs (ITIMs), which recruit Src homology 2 domain-containing in-ositol polyphosphate 5-phosphatase (SHIP).
(2) SHIP disrupts phospholipase Cγ (PLCγ) and Bruton’s tyrosine kinase(Btk) activation.
RHOGAM THERAPY
• Hemolytic disease of the newborn (erythroblastosis fetalis) is caused when an Rh-negativemother produces IgG antibodies to the Rh antigens of her fetus.
• Fetal anemia and jaundice occur when these antibodies cross the placenta.
• To prevent this condition, Rh-negative mothers are given Rhogam (Rh-specific γ-globulin) during andimmediately after pregnancy.
• Rhogam prevents immunization of the mother by clearing fetal erythrocytes from her blood circula-tion.
• Rhogam also cross-links the BCR and FcγRIIB on maternal B cells and inhibits maternal B cell activation.
4. IgG immune complex binding to macrophage Fc�RI (CD64) also induces therelease of IL-10, transforming growth factor (TGF)-�, and prostaglandinE2 (PGE2), all of which inhibit lymphocyte activation.
5. Antibodies produced against the idiotypic determinants of a BCR can inhibit Bcell activation.a. Autoantibodies against idiotypes are produced regularly during adaptive im-
mune responses.b. Antiidiotype antibodies can block B cell activation by cross-linking the BCR
to FcγRIIB.
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6. When high circulating antibody concentrations are achieved, the rate of Ig ca-tabolism also increases.
INTRAVENOUS IMMUNOGLOBULIN (IVIG) THERAPY IN MULTIPLE MYELOMA
• Multiple myeloma is characterized by pancytopenia due to the depression of hematopoiesis by the ma-lignant cells within the bone marrow.
• This causes a functional hypogammaglobulinemia (ie, decreased production of useful antibodies)and increases the risk of infections.
• Prophylactic treatment with IVIG has not always proven useful for correcting this defect.
• The extremely high circulating levels of the M component cause an elevated clearance rate for all Ig,which limits the lifespan of exogenous IVIG.
IV. CD4+CD25+ regulatory T cells (Treg cells) mediate immune homeostasis. A. Treg cells suppress immune responses by several mechanisms.
1. They consume IL-2 and deprive other lymphocytes of its growth-promotingactivity.
2. Treg cells inhibit activated T cells by cell–cell contact and the secretion of theinhibitory cytokines IL-10 and TGF-�.
3. Treg cells are induced late in immune responses and act by suppressing T celleffector functions.
B. Treg cells prevent immune-mediated diseases.1. Treg cells limit host tissue damage that might otherwise occur during exuber-
ant immune responses to microbes.2. Treg cells assist in the maintenance of self tolerance and prevent autoimmunity.
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AgImmunecomplex
Antibody
BCR FcγRII
Off
Figure 11–1. Mechanism by which immune complexes inhibit B cell activation.BCR, B cell receptor.
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THE IMMUNOLOGICAL ENIGMA OF PREGNANCY
• In human pregnancies, the fetus is generally considered a semiallograft (ie, half of its tissue antigensare genetically foreign to the mother) (Chapter 17).
• It is not clear why such a foreign tissue graft is not rejected by the mother, but several mechanisms ap-pear to contribute to fetal survival.
• Trophoblastic cells that form the fetal interface with the maternal circulation are devoid of most HLAantigens and certain costimulatory molecules, such as B7.
• Inhibitory factors, including IL-10, B7 isoforms, death receptor ligands, and PGE2, are expressed at highlevels at sites of implantation.
• Some fetal cells do cross the placenta and are tolerated by the mother’s immune system for years afterpregnancy, suggesting a central immune anergy.
V. Polymorphisms exist in genes that regulate immune functions.A. Dozens of genes that control immune cell differentiation and activation have been
described, some of which will be discussed in Chapter 16. 1. The majority of heritable defects in adaptive immunity have been genetically
mapped, and the gene products have been identified. 2. Much less is known about human genetic polymorphisms or mutations linked
to defects in innate immunity. B. Functionally significant mutations and polymorphisms in genes affecting comple-
ment components, components of antigen presentation pathways, cytokines, cy-tokine receptors, and Ig switch recombinases have been described.
VI. Dysregulation of the immune system can cause immunological diseases. A. Autoimmunity occurs when self-tolerance is lost (Chapter 16).
1. T cells specific for autoantigens can be activated when coreceptor ligands (eg,B7) are abnormally expressed.
2. B cells that produce high affinity autoantibodies can be activated by costimula-tory signals derived from infection.
3. Defects in apoptosis (eg, Fas mutations) can result in a failure to delete autore-active T cells.
B. Adaptive immune responses to microbial antigens can cross-react with self tissueantigens and cause immune-mediated tissue damage.
RHEUMATIC FEVER
• Rheumatic fever in school age children is a complication secondary to pharyngitis caused by the bac-terium Streptococcus pyogenes.
• Damage to the heart and joints appears 2–4 weeks after the pharyngitis.
• Antibodies produced against the streptococcal M protein cross-react with cardiac autoantigens.
• Autoantibodies to myosin, keratin, and laminin play a key role in cardiac valve damage.
C. Atopic allergies result when excessive immune responses are made to relatively in-nocuous environmental antigens (Chapter 13).1. Immune dysregulation causes Th2 polarization.2. IgE antibody production favors acute inflammatory responses.
D. Immune responses to microbes can exceed what is necessary to clear the pathogen.
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1. Inflammatory bowel disease results from immune responses to microbial florathat initiate chronic inflammation.
2. Infectious mononucleosis is caused by an excessive CD8+ T cell response toEpstein–Barr virus antigens that damages host tissues.
SEPSIS REVISITED
• Sepsis is a systemic inflammatory response to infection and one of the leading causes of death amonghospitalized patients.
• The disease also illustrates what happens when immune mechanisms designed to protect the host areexcessively activated (Figure 11–2).
• A complex pathogenesis results from the activation of multiple host defense systems by pathogenicand opportunistic microbes.
• Bacterial components, including lipopolysaccharide (LPS), can activate the complement, coagulation,and fibrinolysis systems.
• Macrophage activation for the production of proinflammatory cytokines (eg, TNF-α) and arachidonicacid metabolites results from Toll-like receptor stimulation.
• Endothelial and smooth muscle cells are activated, resulting in coagulopathies, severe hypotension,impaired organ perfusion, and hypoxic tissue damage.
CLINICALCORRELATION
Pathogenicmicroorganism
Clinical entity Localinfection
Sepsissyndrome
Adultrespiratory
distresssyndrome
Sepsis Septicshock
Multiorganfailure
DeathLocal
inflammatoryresponse
Systemicinflammatory
response
Systemicinflammatoryresponse plushypotensionand evidenceof inadequate
organ perfusion
Renalfailure
Severecadiovascularinsufficiency
Respiratoryinsufficiency
Hepaticfailure
Metabolicfailure
Gastrointestinalfailure
Immune systemfailure
Central nervoussystem failure
Hematologicfailure
Pathophysiology
Figure 11–2. Pathogenesis and clinical definitions associated with the sepsis process.
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CLINICAL PROBLEMSClinical vaccine trials using a nine-amino acid peptide immunogen from an HIV-1 glyco-protein have been performed. The vaccine is effective at inducing high-affinity IgG virus-neutralizing antibodies in only a subset of healthy adult vaccinees.
1. Which of the following immune properties probably characterizes the responsive indi-viduals?
A. They share HLA class II genes.
B. They lack Treg cells.
C. They are high producers of IL-10.
D. They lack IL-2 receptors.
E. They are all over 70 years of age.
A patient with lupus presents with impaired renal function, and a biopsy shows IgG andC3b deposits in the renal glomerulus. The patient’s serum contains antibodies to herDNA and erythrocytes. Her total IgG is significantly elevated (1900 mg/dL).
2. Which of the following best explains the hypergammaglobulinemia seen in this pa-tient?
A. Reduced clearance of IgG by the damaged kidney
B. Destruction of Treg cells by anti-DNA antibodies
C. Polyclonal B cell activation by numerous self antigens
D. An opportunistic virus infection
E. Depletion of serum complement
Mary is a 2-year-old child with an unremarkable medical history, but presents today withenlarged cervical lymph nodes. Her complete blood count shows lymphocytosis(10,500/µL) and her serum contains elevated concentrations of IgG and IgM. Flow cy-tometry indicates that her CD3+ lymphocytes are 25% CD4+ and 20% CD8+. She has nohistory of recurrent infections and no evidence of a current infection or cancer.
3. Which of the following is the most likely basis for Mary’s immune abnormalities?
A. HIV-1 infection
B. IgA deficiency
C. Thymic hypoplasia (DiGeorge syndrome)
D. An apoptosis defect (Fas deficiency)
E. A monoclonal gammopathy
A 2-month-old healthy child is immunized with a new bacterial protein vaccine as part ofa clinical trial. His preimmunization titer of IgG antibody to the vaccine protein is 1:16,and the titer is unchanged 2 weeks postimmunization.
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4. Which of the following is a likely explanation for this observation?
A. The child has had an infection with the bacterium during gestation.
B. Maternal antibody to the bacterial protein blocked active immunization of thechild.
C. The child has severe combined immune deficiency.
D. The child has a Th cell defect that prevents Ig class switching.
E. Children cannot make antibodies at this age.
ANSWERS
1. The correct answer is A. The high responding vacinees probably share HLA antigensthat can present the peptide vaccine. Because this is an exogenous antigen, class II mol-ecules would be involved. Presumably, the HLA class II molecules of the nonrespon-ders failed to bind and present the peptide.
2. The correct answer is C. Elevated IgG levels in this patient are probably due to poly-clonal B cell activation by autoantigens. Most patients of this type produce autoanti-bodies to a wide range of self antigens, suggesting that they have defects in general im-mune regulation mechanisms.
3. The correct answer is D. Mary has an unusual pattern of T cell markers. Only 45% ofher T cells express either CD4 or CD8; the remaining T cells are apparently doublenegative. This is a classic sign of ALPS (Chapter 10). The condition arises from a defectin apoptosis among T cells resulting from a Fas mutation. Her elevated immunoglobu-lins probably represent autoantibodies against a range of self antigens, because self-reactive T cells are not controlled by Fas-mediated apoptosis.
4. The correct answer is B. The IgG antibodies present prior to immunization were prob-ably maternally derived, because children of this age do not synthesize much IgG. Thefact that the titer did not increase following immunization seems to indicate that thematernal antibodies interfered with B cell activation. This would occur if the vaccineand preformed maternal antibodies formed immunosuppressive immune complexesand cross-linked the BCR and FcγRIIB.
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I. Cytokines mediate cell–cell communication in the immune system.A. Cytokines are 8- to 25-kDa polypeptides that include interleukins (IL),
chemokines, growth factors (GF), interferons (IFN), and colony-stimulatingfactors (CSF) (Appendix II).
B. Most cytokines are designed for rapid, short-term effects.1. They are often secreted immediately after their synthesis.2. Their short half-lives in circulation reflect the action of inactivators and bind-
ing proteins.C. Cytokines typically act over short distances.
1. Many cytokines (eg, IL-2) have autocrine effects; they act on the cells that pro-duce them.
2. Other cytokines have localized paracrine effects; one cell produces a cytokinethat acts on a nearby cell.
3. Cell–cell contact promotes the action of cytokines.4. A few cytokines show endocrine effects; they act at a distance after secretion
into the blood stream.a. Tumor necrosis factor (TNF)-α produced by tissue macrophages during
bacterial infections can have systemic inflammatory effects. b. IL-1β produced during inflammation or infections causes fever by its en-
docrine effects on the hypothalamus. D. Cytokines activate cells through specific high-affinity receptors.
1. Dissociation constants for cytokine receptors are in the picomolar range.2. Receptors for cytokines that mediate acute inflammatory or innate immune re-
sponses are typically constitutively expressed.3. Receptors for lymphocyte-activating cytokines are often induced. 4. The same receptor for a given cytokine may have significantly different effects
when expressed on different cell types.E. The most common cellular response to a cytokine is the rapid initiation of gene
transcription. F. Cytokines have redundant biological effects (Table 12–1).
1. This ensures that a deficiency of one cytokine does not eliminate an essentialbiological function.
2. Cytokine redundancy frustrates anticytokine therapies.G. Most cytokines are pleiotropic; they exhibit several functions.
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H. When combined, cytokines can have synergistic effects.1. One cytokine may induce the expression of receptors for the second cytokine. 2. Distinct cytokine receptor signaling pathways can converge at the same cellular
response (eg, NFκB activation). I. Cytokines can amplify a biological response by inducing additional cytokine syn-
thesis (Figure 12–1). J. Certain cytokines antagonize the effects of other cytokines.
1. IFN-γ inhibits the effects of IL-4 on B cells.2. IL-10 and transforming growth factor (TGF)-β antagonize the effects of IFN-γ
on macrophages. K. There are dedicated inhibitors of cytokines.
1. IL-1 receptor antagonist (IL-1ra) is produced by the same cells that secreteIL-1 and binds to the same receptor.
2. The amino-terminus of TGF-β maintains the secreted cytokine in a latentform until it is removed by proteolysis.
TUBERCULOSIS IN RHEUMATOID ARTHRITIS
• Rheumatoid arthritis (RA) is an autoimmune disease characterized by inflammation of the joints anda progressive loss of joint function.
• New therapies for RA include the use of anticytokine reagents to block the action of TNF-α or IL-1β.
• For example, Etanercept is a recombinant protein consisting of a portion of a TNF receptor (p75) fusedto the Fc portion of human immunoglobulin (Ig) G to prolong its circulating half-life.
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Table 12–1. Redundancies between TNF-α and IL-1β.a
Response TNF-α IL-1β
Fever induction + +
Acute phase protein induction through IL-6 + +
Induction of vascular adhesion molecule expression + +
Induction of IL-8 + +
Activation of NFκB + +
Joint inflammation in rheumatoid arthritis + +
Systemic inflammatory response syndrome (SIRS) + +
Cachexia + −
Induction of apoptosis + −
aTNF, tumor necrosis factor; IL, interleukin.
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• Combining an anti-TNF-a and an anti-IL-1b drug in these patients increases the risk of pulmonary tu-berculosis.
• This finding emphasizes the importance of using anticytokines under conditions that inhibit inflam-mation without impairing innate host defenses.
II. Macrophages, natural killer (NK) cells, and NKT cells are important sourcesof proinflammatory cytokines that also mediate innate immunity (Table12–2).
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Macrophage activation; killing of phagocytosed microbes
Microbes
Activation Antigen presentation
Dendritic cellMacrophage
CD40CD40L
TH1 cell
Naive CD4+ T cell NK cell CD8+ T cell
IFN-γ
Interleukin-12 (IL-12)
Stimulation of IFN-γ secretion
Figure 12–1. A cytokine cascade. NK, natural killer; IFN, interferon.
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A. These cells bear receptors that recognize both conserved microbial structures andendogenous ligands derived from damaged host cells.1. Macrophages express Toll-like receptors (TLRs) (Table 1–2).2. NK cells and NKT cells recognize exogenous and endogenous ligands from in-
fected, stressed, or injured host cells (Table 10–4).B. The cytokines produced by these cells signal danger to phagocytes and endothelial
cells.1. TNF-α has the following functions.
a. It stimulates the expression of adhesion molecules and integrins on en-dothelial cells and leukocytes, respectively.
b. It primes neutrophils and macrophages for respiratory bursts and NO pro-duction.
c. It induces the synthesis of acute phase proteins.d. It induces apoptosis through its death domain-containing receptor.
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Table 12–2. Cytokines that mediate innate immunity and acute inflammation.a
Important Biological Function Cytokines Specific Examples
Leukocyte adhesion TNF-α Induces ICAM-1 expression on endothelium
Chemotaxis TGF-β Recruits blood monocytesIL-8 Recruits blood neutrophils
Induction of other IFN-γ Promotes macrophage activation inflammatory mediators for IL-1 and TNF-α production
Fever induction IL-1β Activates cells of the hypothalamus
Acute phase protein IL-6, IL-1, Activates hepatocytes and Kupffer synthesis TNF-α cells to produce fibrinogen and
complement components
Oxidant production TNF-α Activates neutrophils for superoxide production
IFN-γ Activates macrophages for NO production
Inhibition of immunity IL-10, Inhibits TNF-α synthesis by IFN-γ-TGF-β activated macrophages
Apoptosis TNF-α LT, Apoptosis of tumor cellsIL-2 Activation induced cell death in
T cells
aTNF, tumor necrosis factor; ICAM, intercellular adhesion molecule; TGF, transforming growth fac-tor; IL, interleukin; IFN, interferon; LT, leukotriene.
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2. IL-1β has the following functions. a. It is redundant with TNF-α (Table 12–1).b. It synergizes the effects of TNF-α.c. It induces fever by stimulating the hypothalmus.
3. IL-12 has the following functions.a. It coactivates NK cells and T cells.b. It coinduces IFN-γ production and cytotoxicity by NK cells and NKT
cells.c. It induces the differentiation of CD4+ Th1 cells.
4. IFN-γ (type II interferon) has the following functions. a. It activates macrophages.b. It induces the production of other proinflammatory cytokines, including
TNF-α, IL-1β, IL-6, and the chemokine CCL4.c. It promotes major histocompatibility complex (MHC) class II gene ex-
pression.d. It promotes the differentiation of CD4+ Th1 cells.
5. Type I interferons (IFN-α/β) have the following functions. a. They block virus replication by autocrine signaling.b. They increase MHC class I expression.c. At low levels they coactivate macrophages.d. At high concentrations they inhibit macrophage and lymphocyte activation.
6. Chemokines have the following characteristics.a. Chemokines are chemotactic cytokines that are produced rapidly in re-
sponse to the danger signals associated with infection and inflammation.b. They attract cells to sites of infection or inflammation.
C. The proinflammatory effects of these cytokines are balanced by antiinflamma-tory cytokines (eg, IL-10), cytokine-binding proteins, and receptor antago-nists (see above).
D. The amount of a cytokine that is secreted determines its overall effects.1. In low to moderate levels of production, proinflammatory cytokines initiate
important innate mechanisms of host defense.2. When produced at high concentrations, proinflammatory cytokines cause the
systemic inflammatory response syndrome (SIRS). a. Sepsis is a form of SIRS initiated by infection (Chapter 11).b. SIRS can be induced by any stimulus that activates large numbers of inflam-
matory cells and mediators.
SYSTEMIC INFLAMMATORY RESPONSE SYNDROME (SIRS)
• SIRS is defined as a constellation of clinical signs and symptoms, including hyperthermia (> 38°C) orhypothermia (< 36°C), tachycardia (> 90 bpm), tachypnea (> 20 breaths/min), and/or alteredwhite blood cell (WBC) counts (> 12,000/mL or < 4,000/mL).
• Septicemia (microbes in the blood stream) and microbial toxemia (toxins in the blood stream) areamong the leading causes, in which case the syndrome is called sepsis or septic shock.
• Regardless of the initiating event, proinflammatory cytokines play a central role.
• Multiorgan dysfunction, including acute respiratory distress syndrome, is a common sequela.
• Mortality rates when multiorgan failure is present approach 90%.
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E. Cytokines of innate immunity are secreted in a temporal sequence. 1. TNF-α is produced early and promotes leukocyte localization at sites of infec-
tion.2. Chemokines are produced early as a means of recruiting leukocytes to affected
tissue sites. 3. Cytokines that activate phagocytes (eg, IFN-γ) are produced somewhat later.
III. Cytokines of adaptive immunity provide coactivating signals for lympho-cytes and regulate antigen-presenting cells.A. Cytokines that induce humoral immunity are concerned with B cell recruitment,
activation, growth, and differentiation.1. IL-2 from CD4+ Th1 cells induces B cell proliferation and increases Ig and J
chain synthesis.2. IL-4 from CD4+ Th2 cells promotes Ig class switching to IgE, induces the
differentiation of naive CD4+ T cells into Th2 cells, and antagonizes IFN-γ-driven Ig class switching to IgG3.
3. IL-5 and TGF-β promote the synthesis of IgA by B cells.4. The chemokine CCL7 directs antigen-stimulated B cells to T-dependent areas
of the lymph nodes. 5. The coactivating effects of IL-4 on B cells are balanced by the inhibitory effects
of IFN-γ. B. Cytokines that promote cellular immunity induce the activation, growth, and/or
differentiation of T cells, NK cells, NKT cells, and macrophages.1. IL-2 has the following characteristics.
a. It is an autocrine growth factor for many CD4+ and CD8+ T cells.b. It enhances the cytotoxic activity of NK cells and conventional CD8+ T cells. c. It costimulates T cells for the production of IL-4, IL-5, and IFN-γ.d. It promotes the development of Treg cells.e. It induces autocrine activation-induced cell death in T cells (Chapter 11).
2. IFN-γ has the following characteristics.a. It is primarily produced by CD4+ Th1 cells and CD8+ T cells during adap-
tive immune responses. b. It activates macrophage intracellular killing of microbes.c. It increases both class I and class II antigen presentation pathways by in-
creasing MHC, transporter associated with antigen processing (TAP) pro-tein, the proteasome subunits, and HLA-DM expression (Chapter 7).
d. It promotes Th1 polarization by naive CD4+ T cells.e. It inhibits Th2-associated humoral immunity.
DEFICIENCY IN IFN-γ SIGNALING
• Genetic deficiencies have been described for either chain of the heterodimeric IFN-γ receptor.
• Patients with these defects are susceptible to infections by viruses and Mycobacterium and Salmo-nella species, two intracellular bacterial pathogens.
• The same phenotype is associated with defects in the expression of either IL-12 or the IL-12 receptor, il-lustrating the importance of IL-12 as an inducer of IFN-γ.
3. Lymphotoxin (LT or TNF-β) has the following characteristics.a. It is produced by activated T cells.
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b. It has many of the same proinflammatory and apoptosis-inducing effects asTNF-α.
4. TGF-β is chemotactic for blood monocytes.
IV. Cytokines, referred to as colony-stimulating factors (CSFs) or poietins,coordinate the diverse process of hematopoiesis (Figure 12–2). A. Stem cell factor (SCF) and IL-3 have broad growth-promoting effects on multi-
ple blood cell lineages.B. Lymphopoiesis is regulated by IL-7 (T and B cells), IL-2 (T cells), and IL-15
(NK cells).
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Self-renewingstem cell
Pluripotentstem cell
Lymphoid progenitor
Myeloid progenitor
Natural (NK) cell
T lymphocytes
B lymphocytes
Erythroid CFU
ErythrocytesPlatelets Basophils Eosinophils Neutrophils Monocytes
Megakaroyocyte Basophil CFU Eosinophil CFU Granulocyte-monocyte CFU
Erythropoietin
Stem cellfactor
Erythropoietin
IL-3, GM-CSF,IL-1, IL-6
IL-5
Thrombopoietin; IL-11 ? IL-5
IL-3, GM-CSF,M-CSF
IL-3, GM-CSF,G-CSF
Thymus; IL-7, others
IL-15
IL-7
Figure 12–2. Cytokines that regulate hematopoiesis. IL, interleukin; GM-CSF,granulocyte/macrophage colony-stimulating factor; CFU, colony-forming unit.
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C. Myelopoiesis is controlled by erythropoietin (EPO)(erythrocytes), thrombopoi-etin (platelets), IL-5 (eosinophils), granulocyte/macrophage (GM)-CSF and G-CSF (neutrophils), and GM-CSF and M-CSF (monocytes).
D. Recombinant CSFs are now used routinely to correct certain defects inhematopoiesis.
ANEMIA AND ERYTHROPOIETIN
• Anemia is a reduction in red cell mass and has a number of causes, including depressed erythropoiesis.
• Chronic diseases, such as renal failure, malignancy, autoimmune diseases, and certain infections, areoften accompanied by decreased EPO production.
• For the treatment of anemia associated with end-stage renal disease, EPO has replaced blood transfu-sions as a therapy.
• Repeated transfusions of whole blood to prospective renal transplant recipients often immunizes themagainst the HLA antigens of the blood donors.
• This can result in antibody-mediated hyperacute rejection of a subsequent transplant (Chapter 17).
V. Chemokines, a diverse family of chemotactic cytokines, regulate normal celltraffic, tissue architecture, and inflammatory cell recruitment.A. Chemokines establish a chemical concentration gradient that is sensed by the cell.B. They induce the expression of leukocyte integrins that mediate leukocyte binding
to and migration between vascular endothelial cells.C. Chemokines induce cytoskeletal changes that mediate cell migration.D. The two largest chemokine families are designated CCL# or CXCL# (distin-
guished by the arrangement of their cysteine residues)(Table 12–3). 1. CCL chemokines attract monocytes, lymphocytes, and eosinophils.2. Most CXCL chemokines attract neutrophils, although some act on lympho-
cytes.
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Table 12–3. Examples of CC and CXC chemokines and their receptors.a
Chemokine (Ligand) Also Known as Receptors Cells Attracted
CCL4 MIP-1β CCR5 T cells, NK cells, DC,and monocytes
CCL11 Eotaxin CCR3 Eosinophils, basophils,Th2 cells
CXCL2 ENA-78 CXCR2 Neutrophils
CXCL8 IL-8 CXCR1, CXCR2 Neutrophils
CXCL10 IP-10 CXCR3 T cells
CLINICALCORRELATION
aMIP, macrophage inflammatory protein; NK, natural killer; DC, dendritic cells; ENA-78, epithelialneutrophil-activating protein 78; IL, interleukin; IP-10, interferon-γ-inducible protein 10.
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Table 12–4. Cytokine receptor families.a
Receptor Family Ligands Signaling Mechanism
Type I (hematopoietic) IL-2, 3, 4, 5, 6, 7, Jak activation of latent, preformed 12, 13, 15, STAT transcription factorsG-CSF, GM-CSF
Type II (interferon-like) IFN-α/β, IFN-γ, Jak activation of latent, preformed IL-10 STAT transcription factors
TNF TNF, LT, CD40L, Binding of adapter proteins and FasL activation of NFκB and AP-1
Binding of adapter proteins and activation of caspases
Ig superfamily IL-1, M-CSF, SCF Binding of adapter proteins and activation of latent NFκB
Seven-transmembrane Chemokines GTP exchangeG protein coupled Activation of PLC and PI3K
aIL, interleukin; Jak, Janus kinase; STAT, signal transducers and activators of transcription; GM-CSF,granulocyte/macrophage colony-stimulating factor; IFN, interferon; TNF, tumor necrosis factor; LT,leukotriene; SCF, stem cell factor; PLC, phospholipase C; PI3K, phosphatidylinositol-3′-kinase.
E. Chemokine production is induced by a variety of immune and inflammatorystimuli, including TNF-α, IL-1β, IFN-γ, and IL-4.
F. Cellular responses to chemokines are mediated by seven-transmembrane, G pro-tein-coupled cell surface receptors designated CCR# or CXCR#.
G. Some chemokine receptors serve as coreceptors for virus entry.1. HIV-1 uses both CCR5 and CXCR4 as coreceptors with CD4.2. The tissue distribution of these chemokine receptors specifies the tissue tropism
of a particular HIV-1 clone.
VI. Cytokines activate cells by binding to high-affinity receptors (Table12–4)A. Cytokine receptors induce gene expression by activating latent cytosolic transcrip-
tion factors.B. The type I (hematopoietic) receptors activate the Janus kinase (Jak) signaling
pathway.1. Jak is a family of receptor-associated tyrosine kinases that is activated upon re-
ceptor clustering. 2. Jak phosphorylation of cytokine receptors recruits signal transducers and acti-
vators of transcription (STAT) peptides.3. Jak phosphorylates STAT peptides and the peptides dimerize.4. Dimerization of STAT results in nuclear localization, DNA binding, and tran-
scriptional activation.
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5. The receptors for IL-2, 3, 4, 6, 7, 12, and 13, G-CSF, and GM-CSF utilizethe Jak/STAT pathway for signaling.
C. Type II interferon-like receptors for IFN-α/β, IFN-γ, and IL-10 also signalthrough Jak/STAT.
D. The TNF receptor family utilizes adapter proteins to activate diverse signalingpathways.1. When adapter proteins with death domains are recruited, caspase activation
signals apoptosis.2. When adapters without death domains are recruited, kinase activation results
in the activation of NFκB.E. The Ig superfamily of receptors, such as the IL-1 receptor, activates NFκB using
specialized adapter proteins (eg, MyD88) (Figure 1–3).F. G protein-coupled chemokine receptors signal through phospholipase C (PLC),
phosphatidylinositol-3′-kinase (PI3K), and guanosine triphosphate (GTP) ex-change proteins.
G. Different forms of the IL-2 receptor show different affinities for IL-2. 1. Resting T cells, B cells, and NK cells express the β and γc chains of IL-2R,
which shows a moderate affinity for IL-2 (10−9 M).2. Activated T cells express an additional α chain in their IL-2R, which increases
receptor affinity to 10−11 M.
COMMON γ CHAIN (γC) DEFICIENCY
• Whereas cytokine deficiencies are extremely rare, an X-linked recessive cytokine receptor defect is themost common cause of severe combined immune deficiency.
• Mutations in the common γ chain (γc) impair the development of T cells and NK cells, because the re-ceptors for IL-2, IL-4, IL-7, and IL-15 share the γc subunit.
• The resulting T−B+NK− phenotype places these infants at risk for infections with intracellular pathogens.
CLINICAL PROBLEMSA 5-month-old male patient presents with enlarged lymph nodes, and a biopsy showsacid-fast bacteria, a feature of infections with mycobacteria. The patient shows a normalcomplete blood count (CBC) and differential, normal T and B cell subsets by flow cytom-etry, and normal serum Ig levels when referenced to age-matched controls.
1. For which of the following cytokines would a mutation in its receptor explain this clin-ical picture?
A. IL-1
B. IL-2R
C. TNF-�
D. IFN-γE. IL-10
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2. Which of the following additional cytokine deficiencies would produce a similar phe-notype?
A. IL-12 deficiency
B. IL-7 deficiency
C. IL-15 deficiency
D. SCF deficiency
E. IL-4 deficiency
A patient who received a cardiac transplant from an unrelated donor is given the drug cy-closporine to control rejection of his allograft.
3. Which of the following receptors signals through an intermediate that is sensitive to thedrug cyclosporine?
A. IL-1 receptor
B. IL-2 receptor
C. T cell receptor (TCR)
D. TLR4
E. CXCR4
The blood lymphocytes of a 6-month-old child with recurrent, complicated viral and fun-gal infections do not respond normally to IL-2 and IL-4 in vitro. The patient currently hasthrush and a cytomegalovirus (CMV) infection. The patient has a single gene mutationthat explains all of these findings.
4. Which of the following immune functions might you expect to be normal in thischild?
A. Neutrophil ingestion of bacteria
B. NK cell killing of virus-infected cells
C. T cell activation by antigen + antigen-presenting cells (APCs)
D. Ig class switching by B cells cultured with the patient’s T cells
E. Killing of CMV-infected cells by CD8+ cells
A menstruating teenager presents to the emergency room in shock and is diagnosed as suf-fering from toxic shock syndrome secondary to a vaginal infection with the bacteriumStaphylococcus aureus.
5. Which of the following cytokines is both key to host defense against this organism anda central mediator of toxic shock pathogenesis?
A. IL-10
B. TNF-αC. IL-3
D. TGF-βE. IL-5
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ANSWERS
1. The correct answer is D. Mutations in the IFN-γR result in susceptibility to intracellu-lar pathogens (bacterial and fungal) early in life. This probably results from the failureto activate infected macrophages, a cell type commonly infected by these pathogens.
2. The correct answer is A. Because of its role as a coinducer of IFN-γ, IL-12 is also essen-tial for the induction of cellular immunity to intracellular bacterial pathogens, such asthe mycobacteria. Defects in the IL-12R produce a similar clinical picture.
3. The correct answer is C. None of the cytokine receptors signals through a cyclosporine-sensitive pathway, although the production of IL-2 and IL-4 by activated T cells is in-hibited by the drug. Cyclosporine inhibits calcineurin and the activation of nuclearfactor of activated T cells (NFAT), which induces transcription of genes in T and Bcells.
4. The correct answer is A. The only known gene defect that could interfere with re-sponses to both IL-2 and IL-4 is a mutation in the γc chain of the IL-2R and IL-4R.This defect also blocks IL-15R signaling, which would result in an absence of NK cells.The overall phenotype in the periphery would be T−B+NK−.
5. The correct answer is B. TNF-α is a key mediator of both toxic (Chapter 6) and septicshock (Chapters 1 and 12). Toxic shock is initiated when superantigens produced bycertain microbes, including the gram-positive Staphylococcus, activate Th cells andmacrophages by cross-linking TCRs to MHC class II molecules. Massive cytokine pro-duction results when both cell types are activated.
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I. Robust immune responses, even to relatively nonthreatening antigens,can cause host tissue damage.A. An allergy (or hypersensitivity) is an adaptive immune response to an environ-
mental antigen that damages tissues and causes organ dysfunction.1. Allergy is mediated by specific antibodies and/or effector T cells.2. The signs and symptoms of allergy include watery eyes, runny nose, sneezing,
coughing, wheezing, and pruritic (itchy) hives. 3. An allergen is an antigen that can produce these signs and symptoms (Table
13–1).4. Typical allergens include pollens, animal dander, insect venoms, and foods.
B. Atopic allergies are familial, rapid, and strong reactions mediated by im-munoglobulin (Ig) E.1. Atopy is a heritable predisposition to produce IgE antibodies and other allergic
mediators in response to environmental antigens.2. Atopic conditions are more common in developed countries with high levels of
air pollutants and closed living spaces.3. Common manifestations of atopic allergies are allergic rhinitis, allergic
asthma, atopic dermatitis, and allergic anaphylaxis. C. Anaphylaxis is a systemic form of allergy involving the cardiovascular, respiratory,
cutaneous, and gastrointestinal systems. 1. Anaphylactic shock includes hypotension, tissue hypoxia, and the loss of con-
sciousness.2. Anaphylactoid shock is similar in its presentation, but is not mediated by IgE.
a. IgG antibodies mediate systemic anaphylactoid reactions. b. Complement-mediated mast cell activation produces anaphylaxis-like symp-
toms. D. Allergies can develop to inhaled, ingested, or injected antigens or antigens en-
countered by contact with the skin (Table 13–1).1. Tree and grass pollens induce seasonal rhinitis and conjunctivitis.2. Peanuts, shellfish, eggs, and dairy products often cause food allergies.3. Insect and snake venoms and injected drugs (eg, penicillin) can cause allergic
anaphylaxis. 4. Plant resins (eg, poison ivy pentadecacatechol), industrial chemicals, and
metals can cause allergic contact dermatitis.
NC H A P T E R 1 3C H A P T E R 1 3
IMMUNE TISSUE INJURY
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E. Gell and Coombs first described the four major mechanisms of immune tissue in-jury that underlie human hypersensitivies (Table 13–2).1. The mechanisms differ in terms of the nature of the antigen, the immune com-
ponents involved in their pathogenesis, and the nature and onset of clinicalsymptoms.
2. Antigenic specificity is mediated by antibodies and/or T cells.3. Tissue damage results from the activation of complement, mast cells, neu-
trophils, macrophages, or lymphocytes. 4. Immune tissue injury mediated by the innate immune system is not included
in the Gell and Coombs classification scheme.F. Immune tissue injury mediated by adaptive immunity requires two phases.
1. Sensitization occurs on first exposure to the allergen (Figure 13–1).a. Antibody production and/or the proliferation of T cells occur during the
sensitization phase. b. Antibody can either bind to cellular Fc receptors or remain in the circula-
tion, depending on Ig class.c. Tissue damage is not generally seen during the sensitization phase.
2. During the elicitation phase, antibodies or immune T cells recognize the aller-gen and trigger effector mechanisms.a. For example, large numbers of memory CD4+ Th1 cells are activated to pro-
duce cytokines. b. Allergen–antibody complexes activate complement to produce inflamma-
tory peptides.
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Table 13–1. Common allergies and allergens.
Clinical Manifestations Typical Sources of Allergens
Atopic allergic rhinitis and Tree and grass pollens, mold spores, mites in house allergic asthma dust, pet dander
Allergic gastroenteritis Food products (milk, eggs, shellfish)
Occupational allergies Pharmaceuticals, organic and inorganic compounds, enzymes, microbial agents, dyes, plant products, shellfish, animal products
Urticaria and anaphylaxis Foods (shellfish, nuts, seeds), drugs (polypeptide hormones, enzymes, haptenic drugs, opiates), insect venoms
Contact dermatitis Nickel and other metals, formaldehyde, epoxy resins,neomycin cream, benzocaine, plant resins
Drug allergies β-Lactam antibiotics, NSAIDsa
aNSAIDs, nonsteroidal antiinflammatory drugs.
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c. Mast cells with IgE antibodies bound to their surface Fc receptors degranu-late when allergen is encountered.
G. Innate immunity also causes localized tissue damage, but does not require a priorexposure to the foreign agent (ie, a sensitization phase).1. The tissue damage seen in septic arthritis is caused by the activation of neu-
trophils recruited to an infected joint. 2. Innate immune tissue injury can be elicited by relatively nontoxic microbial
products, such as bacterial DNA or cell wall lipopolysaccharide (LPS).a. Sepsis is an acute systemic inflammatory response to infection mediated by
danger signals and the excessive production of inflammatory mediators. b. Responses to components of nonpathogenic microbial flora can induce
organ-specific inflammatory tissue damage.(1) Crohn’s disease is thought to be initiated by innate immune responses
to intestinal microbial flora.(2) Ulcerative colitis appears to involve a similar imbalance of the mucosal
immune system.
CROHN’S DISEASE
• Crohn’s disease (CD) is a chronic transmural inflammation of the large and small bowel that beginswith the loss of epithelial barrier function in the intestine.
• Some CD patients have mutations in the Nod2 antimicrobial protein, which diminishes their ability toclear bacteria that breach the epithelium.
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CLINICALCORRELATION
Table 13–2. The Gell and Coombs classification of immune tissue injury mediated by adaptive immunity.a
Time from Cellular Soluble Exposure to Form of Immune Immune Clinical
Type Response the Antigen Antibodies Mediators Mediators Examples
I Minutes Protein or IgE Mast cells, Histamine, Atopic allergieshapten- basophils, proteases, Allergic asthmaprotein eosinophils eicosinoids,
cytokines, chemokines
II Hours to Cell or IgG or IgM Neutrophils C3b, C3a, Transfusion days tissue bound C4a, C5a reactions
III Hours to Soluble IgG or IgM Neutrophils C3b, C3a, days C4a, C5a Lupus nephritis
IV Days MHC-bound None APCs, T cells, IL-2, IFN-γ, Allergic contact peptide NK cells, chemokines dermatitis
macrophages
aIg, immunoglobulin; MHC, major histocompatibility complex; APC, antigen-presenting cells; NK, natural killer; IL, inter-leukin; IFN, interferon.
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• Aberrant innate immune responses develop in the gastrointestinal tract to the intestinal flora.
• Activated macrophages and Th1 cells produce excessive interleukin (IL)-12, interferon (IFN)-γ, andtumor necrosis factor (TNF)-α.
• Sustained macrophage and neutrophil activation contributes to chronic inflammation.
• Blocking the action of TNF-α with monoclonal antibodies to the cytokine has proven effective in thetreatment of CD.
II. Type I (immediate-type) immune tissue injury (Table 13–2) is a rapidresponse to environmental antigens mediated by IgE antibodies andvasoactive inflammatory mediators released by mast cells.
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Allergen CD4
Fc receptorfor IgE
Allergen IgE antibody
TH cellB cell
IL-4
Plasma cell
Sensitizedmast cell
Vascoactive amines
Degranulation
Memorycell
Blood platelets EosinophilsMucous gland Sensory-nerveendings
Smooth muscleSmall blood vessel
Figure 13–1. The sensitization and elicitation phase of immediate type immune tissue injury. IL-4,interleukin 4; IgE, immunoglobulin E.
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A. The antigens that elicit these responses are proteins or haptens (eg, drugs) thatcan bind to proteins.1. The allergens are presented by major histocompatibility complex (MHC) class
II molecules and activate CD4+ Th2 cells.2. Th2 cells produce IL-4 and IL-13, which induce class switching to IgE.
B. The propensity to make high-titer IgE antibodies to environmental allergens is, inpart, genetically determined.1. Multiple genes control susceptibility to allergy and asthma.2. Among the traits that appear to be genetically controlled are total IgE levels,
Th2 polarization, and mast cell and eosinophil growth.C. Allergen-specific IgE antibodies bind to Fcε receptor I (FcεRI) on tissue mast
cells. 1. FcεRI is a very high-affinity receptor (Kd = 10 pM).2. The activation of mast cells through FcεRI requires receptor cross-linking by
multideterminant antigens. 3. Because the antibodies displayed on mast cells are specific for many different
epitopes, polyvalent protein antigens can cross-link surface FcεRI molecules.D. The tissue distribution and density of mast cells as well as the surface density of
FcεRI determine the distribution of tissue injury.1. The route of immunization (eg, respiratory versus gastrointestinal) determines
the local distribution of antibody specificities on tissue mast cells.2. Mucosal and connective tissue mast cells produce distinct patterns of inflam-
matory mediators.
HYPER-IgE SYNDROME
• Hyper-IgE syndrome or Job’s syndrome is an immune deficiency characterized by recurrent and se-vere staphylococcal skin abscesses and pneumonia.
• Th1:Th2 imbalance results in a decreased production of IFN-γ, a cytokine that normally inhibits Th2 re-sponses, such as switching to IgE production.
• These patients can also show pruritic dermatitis, but increased allergy is not common, despite exceed-ingly high serum IgE levels (> 2000 IU/mL).
E. Signaling through FcεRI results in three mechanisms of inflammatory mediatorrelease (Figure 13–2).1. Preformed mediators stored in cytoplasmic granules are released when mast
cells degranulate.a. Allergen binding triggers FcεRI clustering.b. Phospholipase Cγ (PLCγ) is recruited to the immunotyrosine activation
motifs (ITAMs) of the FcεRI and is activated. c. Protein kinase C (PKC) is then activated by diacylglycerol and phosphory-
lates myosin light chains.d. Cytoskeleton changes are induced that promote granule exocytosis and the
release of granule constituents. (1) The preformed vasoactive amine histamine (Table 13–3) is released.(2) Heparin, the proteases chymase and tryptase, and chemotactic peptides
that recruit neutrophils and eosinophils are also released from granules.e. Degranulation can be inhibited by maintaining elevated levels of intracellu-
lar cyclic AMP (cAMP).
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2. FcεRI cross-linking also activates phospholipase A2 (PLA2). a. PLA2 cleaves phosphatidylcholine to form arachidonic acid. b. Arachidonic acid is metabolized by the cyclooxygenase and lipoxygenase
pathways to form prostaglandins (PGs) and leukotrienes (LTs), respec-tively.
3. The de novo expression of cytokine genes is induced by the activation of tran-scription factors. a. Nuclear factor of activated T cells (NFAT), nuclear factor-κB (NFκB),
and AP-1 are activated in mast cells.b. The genes for IL-3, IL-4, IL-5, IL-6, IL-13, and TNF-α are transcribed.
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Lipid mediators Cytokines Granule contents
PKC
Histamine
PI-PLCγ
PSyk
PGD2 LTC4 LTD4 LTE4
Cytokine gene expression
Cytokine RNA
Nucleus
Secretion
PGD2
Arachidonic acid
PhosphatidylcholinePhosphatidylcholinePhosphatidylcholine
Ras-MAP kinases
LTC4
Secretion
LynP
P
P
P IP3
Ca2+
GranuleMyosin light chainphosphorylation
Exocytosis
FcεRI
Allergen
Ca2+
TNF
Mast cell plasmamembrane
PLA
PIP2 DAG
Figure 13–2. Fcε receptor I (FcεRI) signaling in mast cells. PIP2, phosphatidylinositol 4,5-biphosphate;DAG, diacylglyceride; PLCγ, phospholipase Cγ; IP3, inositol 1,4,5-triphosphate; PLA2, phospholipase A2;MAP, mitogen-activated protein; PKC, protein kinase C; PGD2, prostaglandin D2; LT, leukotriene;TNF, tumor necrosis factor.
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IgE-INDEPENDENT MAST CELL ACTIVATION
• Several agents can activate mast cells without binding as allergens to cell surface IgE.
• Certain drugs (morphine, codeine, calcium ionophores, vancomycin, radiocontrast agents) can acti-vate mast cells directly and induce anaphylaxis.
• The anaphylatoxins C3a, C4a, and C5a trigger mast cell degranulation.
• The neuropeptides substance P and somatostatin mediate cholinergic triggering of asthma by acti-vating mast cells.
• Lectins, such as those found in some foods, can bind carbohydrate residues on IgE and induce adversereactions to foods.
F. The signs and symptoms of allergy reflect the action of mast cell mediators on tar-get tissues (Table 13–3).1. Most of the inflammatory effects of histamine in allergy are mediated through
binding of histamine to H1 histamine receptors.a. H1 receptors are G protein coupled and activate adenylate cyclase.b. Adenylate cyclase activation leads to a transient increase in intracellular
cAMP concentrations. 2. The effects of histamine depend on the cell type affected.
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Table 13–3. Inflammatory mediators derived from activated mast cells.a
Preformed or Proinflammatory Mast Cell Signaling Newly Synthesized Mediators Effects Intermediates
Preformed mediators Histamine Itchy sensation, PLCγ, Ca2+ mobilization, PKC Heparin vasodilation, increased activation, myosin phosphoryla-Tryptase vascular permeability, tion, granule exocytosisChymase bronchoconstriction, E-CFA mucus secretion, N-CFA leukocyte chemotaxis,
gut peristalsis
Newly synthesized PAF, prosta- Vasodilation, increased PLA2 activation, arachidonic acid, mediators glandins vascular permeability, COX-2
(PGD2), bronchoconstriction, NFκB, NFAT, and AP-1 leukotrienes eosinophil chemotaxis, activation(LTC4) mucus secretion,
IL-3, IL-4, platelet aggregation, IL-5, IL-6, ICAM-1 expression, TNF-α, mast cell growth, eotaxin Th2 cell differentiation
aE-CFA, eosinophil chemotactic factor of anaphylaxis; N-CFA, neutrophil chemotactic factor of ana-phylaxis; PLCγ, phospholipase Cγ; PKC, protein kinase C; PAF, platelet-activating factor; IL, inter-leukin; TNF, tumor necrosis factor; ICAM, intercellular adhesion molecule; PLA2, phospholipase A2;COX, cyclooxygenase; NFκB, nuclear factor κB; NFAT, nuclear factor of activated T cells.
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a. Histamine relaxes smooth muscle cells in peripheral blood vessels causingvasodilation.
b. Histamine induces bronchospasms in the lungs and peristalsis in the in-testines by stimulating smooth muscle contraction.
c. Histamine causes contraction of vascular endothelial cells resulting in in-creased vascular permeability and edema.
3. Tryptase and chymase are serine proteases stored in granules.a. The circulating levels of tryptase are a clinical measure of recent mast cell
degranulation.b. Tryptase induces mucus secretion in the lungs.c. Tryptase can activate certain matrix metalloproteases. d. Tryptase cleaves plasminogen to form plasmin, which cleaves C3.
4. Mast cell granules contain two chemotactic peptides.a. Eosinophil chemotactic factor of anaphylaxis (E-CFA) attracts
eosinophils to the lung in asthma and to the intestine in certain parasitic in-fections.
b. Neutrophil chemotactic factor of anaphylaxis (N-CFA) recruits neu-trophils that contribute to tissue damage.
5. Proteoglycans, including heparin and chondroitin sulfate, are granule con-stituents to which other mast cell mediators are bound.
SYSTEMIC ALLERGIC ANAPHYLAXIS
• The allergens that typically induce systemic anaphylaxis include drugs, insect venoms, and certainfoods.
• Key target organs include the cardiovascular, pulmonary, gastrointestinal, and cutaneous systems.
• Typical signs and symptoms of anaphylatic shock include generalized pruritis, apprehension, hypoten-sion, abdominal cramping, tachycardia, tachypnea, and hives.
• Timely injection of epinephrine is life saving.
• Drugs that inhibit the late phase of anaphylaxis are essential to avoid a secondary shock response sev-eral hours later.
6. Three groups of lipid mediators contribute to allergic responses. a. Platelet activating factor (PAF) is derived from the PLA2-mediated hydrol-
ysis of membrane phospholipids.(1) PAF is produced by mast cells, basophils, and endothelial cells.(2) PAF induces vasodilation, bronchoconstriction, and increased vascu-
lar permeability.b. PGs are derived from the metabolism of arachidonic acid via the cyclooxy-
genase (COX) pathway.(1) COX-2 is the principal mast cell cyclooxygenase.(2) PGD2 is the principal prostaglandin produced.(3) PGD2 causes vasodilation and bronchoconstriction.
c. LTs are derived from arachidonic acid by the lipoxygenase pathway. (1) LTC4, LTD4, and LTE4 are the principal leukotriene mediators of al-
lergy. (2) LTC4 is produced by mucosal mast cells, but not connective tissue mast
cells (eg, in the skin).(3) LTC4 is a major cause of bronchoconstriction.
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7. Cytokines are expressed by mast cells following transcription. a. IL-3 and IL-4 promote the growth of mast cells.b. IL-4 and IL-13 induce B cell class switching to IgE.c. IL-5 is a chemotactic factor for eosinophils.d. IL-4 promotes eosinophil growth.e. TNF-α facilitates leukocyte chemotaxis by inducing vascular intercellular
adhesion molecule (ICAM)-1 and leukocyte integrin expression.f. Cytokines mediate many of the late-phase allergic responses.
ALLERGIC ASTHMA
• The allergic form of asthma is caused by IgE-mediated immunity to inhaled allergens.
• Th2 polarization probably begins early in life.
• Asthmatic “attacks” can be triggered by either intrinsic signals (eg, cold outside air or exercise) or ex-trinsic signals (ie, allergens).
• Chronic mast cell activation leads to persistent mediator release, bronchoconstriction (chest tight-ness), mucus secretion, and eosinophil recruitment and activation.
• Eosinophils damage the mucosal epithelium, cause perivascular edema, and initiate lung tissue re-modeling.
• Mucus plugging of the bronchi results in the hyperinflation of the lungs, an inability to expire air, andexpiratory wheezing.
• Early intervention is designed to diagnose and treat the underlying allergic conditions.
• As the disease progresses, more aggressive treatment to control chronic inflammation (eg, corticos-teroids) must be considered.
G. The proper diagnosis of atopic allergies requires a careful patient history and al-lergy skin testing. 1. The diagnostic gold standard for allergy is the skin test.
a. Allergen injected into the skin induces histamine release, localized edema(wheal), and a zone of erythema (flare) within 20 minutes.
b. Negative and positive controls (eg, saline and histamine, respectively) are es-sential to validate the test.
2. The radioallergosorbant test (RAST) is useful for measuring the circulatinglevels of IgE antibodies to known allergens (Chapter 5).
HAY FEVER
• Allergic rhinitis or hay fever can be a perennial or seasonal condition.
• For example, in the Midwest, ragweed pollenosis shows a well-delineated season with symptoms ap-pearing first in mid-August and lasting through the first frost.
• Rhinitis presents as sneezing, nasal congestion, and watery, itchy eyes.
• Typical allergens include pollens, fungal spores, animal dander, and house mites.
• The accurate identification of the allergen requires a careful patient history combined with skin testingusing standardized allergens.
H. Prophylaxis and treatment of allergic conditions take many forms. 1. The first approach to prophylaxis is to avoid the allergen.2. Immunotherapy is an effort to divert the immune system away from IgE-
mediated triggering of mast cells.
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a. The patient receives repeated intradermal injections of the allergen over sev-eral months.
b. Some patients produce IgG and IgA antibodies that compete with allergenicIgE.
c. The IgE antibody levels in some patients decrease by unknown mechanisms.d. A Th2 to Th1 shift in immunity to the allergen may occur.
3. Antibodies to the Fc portion of IgE (omalizumab) are beneficial for treating se-vere allergic asthma (Table 13–4).a. The antibodies decrease circulating levels of IgE.b. They decrease the density of FcεRI on tissue mast cells.
4. Desensitization is a therapy designed to establish a temporary block of aller-gen-induced mast cell mediator release.a. Desensitization is most often used when no alternative therapy exists for a
patient with a drug allergy. b. The patient is given the allergenic drug in incrementally increasing doses be-
ginning with a subclinical dose.c. Desensitization probably results from the gradual, controlled release of mast
cell mediators. d. The desensitized state persists only while the drug is given.
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Table 13–4. Pharmacological treatment of allergy.a
Group Examples Mechanisms of Action Clinical Uses
Anti-IgE Omalizumab Decreasing circulating IgE Asthma
Antihistamines Diphenhydramine, H1 receptor antagonists Allergic rhinitis, urticaria, fexofenadine anaphylaxis
β2-Agonists Epinephrine, β2-Adrenergic agonist Anaphylaxis, asthma, urticariaalbuterol
NSAIDs Indomethacin Blocks PG synthesis Urticaria
Corticosteroids Beclomethasone, Blocks PLA2 and Allergic rhinitis, asthma, methylprednisolone cytokine expression anaphylaxis
Mast cell Cromolyn sodium Prevents granule fusion Allergic rhinitisstabilizers Asthma
Methylxanthines Theophylline Inhibits phosphodiesterase Asthma
Leukotriene Zafirlukast Blocks LT action Asthmareceptor antagonists
aIgE, immunoglobulin E; NSAIDs, nonsteroidal antiinflammatory drugs; PG, prostaglandin; PLA2, phos-pholipase A2; LT, leukotriene.
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5. Inhibiting mast cell degranulation is effective against allergy.a. Cromolyn sodium inhibits Ca2+ influx, an important step in FcεRI signal-
ing.b. Theophylline maintains high intracellular cAMP levels in mast cells.c. Nonsteroidal antiinflammatory drugs (NSAIDs) (eg, indomethasone) in-
hibit arachidonic acid metabolism.d. Hydrocortisone acts at multiple steps in mast cells.
(1) It inhibits histamine synthesis from histidine.(2) It inhibits the activation of PLA2.(3) The drug blocks NFκB activation by increasing the expression of its in-
hibitor IκB.
FOOD ALLERGIES
• Food intolerance can be IgE dependent or IgE independent.
• Most adults show the IgE-dependent form, whereas significant numbers of infants or children havefood intolerance that is not IgE mediated.
• Common allergens include proteins of peanuts, soybeans, shellfish, milk, and eggs.
• Oropharyngeal symptoms (pruritis and urticaria in the mouth) appear first followed by nausea, cramp-ing, vomiting, flatulence, and diarrhea.
• Urticarial rashes and even anaphylaxis can result from allergic reactions to foods.
• IgA deficiency increases the childhood risk of developing IgE-mediated food allergies.
6. Some drugs block the effects of allergic mediators.a. The β-adrenergic receptor agonist epinephrine blocks histamine action.b. Epinephrine is life saving in acute allergic anaphylaxis. c. The β2-receptor agonist albuterol is an effective bronchodilator used for the
treatment of allergic asthma.d. Antihistamines include the H1 receptor antagonists (eg, diphenhydramine
and chlorpheniramine).e. Leukotriene receptor antagonists are used to treat asthma.f. Hydrocortisone and other corticosteroids also block inflammatory gene ex-
pression in target cells.
III. Type II (cytotoxic) immune tissue injury results from the recognition ofcell- or tissue-bound antigens by IgG and IgM antibodies (Table 13–2).A. Tissue damage generally requires hours or days to become evident.B. IgM and IgG antibodies activate complement through the classical pathway.
1. Tissue damage can result from the formation of the membrane attack com-plex C5b-9.
2. C5a is chemotactic for neutrophils.3. C3a, C4a, and C5a are anaphylatoxins that directly activate mast cells.4. Phagocytic cells can cause tissue damage when they attach to IgG- or iC3b-
coated tissues and cells.C. Anemia is a common effect of cytotoxic immune tissue injury directed toward ery-
throcyte antigens. 1. Transfusion reactions result when mismatched blood is transfused to a patient
with a preformed antibody.
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2. Rh disease of the newborn is due to maternal IgG antibodies that cross theplacenta and bind to fetal Rh antigens.
3. A number of autoimmune diseases (eg, Coombs-positive hemolytic anemiasand thrombocytopenias) are mediated by host antibodies reacting with au-toantigens (Chapter 16).
D. Damage to solid tissues and extracellular matrix is also mediated by cytotoxic im-mune tissue injury.1. Hyperacute graft rejection is mediated by anti-HLA antibodies.2. Autoantibodies in Goodpasture syndrome react with type IV collagen of the
glomerular basement membrane.E. The diagnosis of type II immune tissue injury is often based on detecting an ab-
normal distribution of IgG.1. The Coombs test detects Ig on erythrocytes.2. Immunofluorescence can detect IgG deposition within tissues.
IV. Type III (immune complex) tissue injury results when solubleantigen–antibody complexes form in the blood and deposit in tissues. A. Immune complex deposition in the kidneys causes nephritis.B. Immune complexes in the joints result in arthralgia and arthritis.C. Immune complexes in the skin cause a range of lesions, including rashes.D. Immune complex deposition in blood vessel walls causes vasculitis, purpura, and
edema.E. IgG-containing immune complexes activate complement in tissues.
1. C5a attracts neutrophils to sites of immune complex deposition.2. iC3b serves as an adhesion ligand promoting neutrophil binding.3. The membrane attack complex damages cells. 4. Immune complex formation often causes a transient decrease in the serum lev-
els C1, C2, C3, and C4.F. Diagnosis involves the detection of antibodies in the serum or affected tissues.
SERUM SICKNESS
• Serum sickness was first described in the preantibiotic era as a reaction to horse antitoxins given re-peatedly for the treatment of toxin-mediated infectious diseases.
• The condition can arise after antibody production to either protein [eg, intravenous immunoglobulins(IVIG), foreign monoclonal antibodies, vaccines] or nonprotein (eg, penicillin or sulfonamides) anti-gens.
• Serum sickness typically becomes evident 1–3 days after exposure to the antigen.
• Signs and symptoms include fever, rash, hypotension, anaphylactoid purpura, lymphadenopathy,myalgia, arthralgia, and nephritis.
• The treatment of anaphylactoid syndrome is the same as that for anaphylaxis, ie, discontinuance ofthe antigen and administration of epinephrine, antihistamines, and corticosteroids.
V. Type IV (delayed-type) immune tissue injury is a manifestation of cell-mediated immunity to haptens or protein antigens. A. The immunologically specific component of delayed-type hypersensitivity
(DTH) is the Th1 cell, rather than antibody.
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1. Allergens must be proteins or chemically reactive groups capable of binding co-valently to proteins.
2. Important cytokines include IL-1, TNF-α, IL-2, IL-12, IFN-γ, and the CCLgroup of chemokines (Chapter 12).
B. Host tissue damage is mediated by cytotoxic T lymphocytes, natural killer (NK)cells, macrophages, and a range of soluble inflammatory mediators.1. Macrophages and Th1 cells produce the proinflammatory cytokines IL-1, IL-2,
IFN-γ, and TNF-α.2. Macrophages produce eicosinoids (LTs and PGs), hydrolytic enzymes, and re-
active oxygen species. C. The important clinical manifestations of type IV hypersensitivity show delayed
onset (2–3 days) and include contact dermatitis.1. Plant resins (eg, poison ivy pentadecacatechol), metals (eg, nickel) and chemi-
cals (eg, cosmetics) cause a variety of rashes.2. Industrial exposure to certain drugs, including antibiotics, can cause type IV
hypersensitivities.D. Delayed-type hypersensitivity (DTH) skin lesions are initially characterized by
their indurated (firm) nature, rather than the edematous (fluid-filled) lesions ofatopic allergy.
E. The diagnosis of allergic contact dermatitis is aided by the patch test.1. Solutions of test allergens are placed on absorbent skin patches.2. The extent of induration and erythema beneath each patch is determined
48–72 hours later.
CLINICAL PROBLEMSA 44-year-old school teacher who paints houses in the summer presents in early June witherythematous, indurated, and blistering lesions limited to his hands and forearms. The le-sions typically appear each summer within several days of beginning to use painting prod-ucts, including solvents and epoxy resins. He indicates that he does not wear protectivegloves when working with these chemicals. The lesions disappear several weeks after he re-turns to his teaching position in the fall.
1. Which of the following represents a likely step in the pathogenesis of this disease?
A. Activation of C1
B. Chemotaxis of neutrophils
C. Induction of IgE antibodies
D. Antigen presentation by the MHC class II pathway
E. Immune complex deposition
2. Which of the following test results would best fit the clinical findings in this case?
A. A positive skin test after 20 minutes with a dilute solution of epoxy resin
B. A positive skin patch test with a dilute solution of epoxy resin
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C. Decreased serum levels of C1, C2, C3, and C4
D. A decreased CD4:CD8 ratio
E. Elevated serum tryptase
Jim received penicillin for pneumonia several years ago and presented last week with whatappeared to be an allergic reaction to the drug when it was taken for a sinus infection. Thenext day after beginning oral penicillin, Jim’s eyelids became puffy and his abdomen wascovered with itchy, nearly confluent hives. After the administration of diphenhydramineand hydrocortisone his condition improved. Laboratory tests performed on his acuteserum showed an elevated level of tryptase and decreased C1 and C3. A skin test withpenicillin was negative.
3. Which of the elements of this case suggests this reaction was caused by circulating IgGantibody–drug complexes, rather than IgE antibody to penicillin?
A. His plasma tryptase level was elevated.
B. His symptoms were corrected by administering antihistamines.
C. His C1 and C3 levels were decreased.
D. His skin lesions were pruritic (itchy).
E. He showed evidence of altered vascular permeability.
Jesse is a 10-year-old child who complains of chest tightness and wheezing after gym classand upon exposure to cold outside air. He experiences sneezing, nasal itching, and nasalcongestion indoors and following contact with his friend’s dog. His allergist has deter-mined by skin testing that he is allergic to oak pollen, Bermuda grass, house dust, and dogdander. His pulmonary function tests indicate a forced expiratory volume in 1 second(FEV1) < 60% of the expected value for his age and a peak flow rate of 180 L/min (normal> 350 L/min).
4. Which of the following drugs would be most beneficial in alleviating Jesse’s pulmonarysymptoms?
A. Albuterol
B. Anti-TNF-α monoclonal antibody
C. IVIG
D. Cyclosporin
E. Recombinant IL-4
Anna is a 7-year-old child who presents with itchy, erythematous, indurated lesions on herforearms and legs 3 days after a camping trip with her classmates. Her mother treats Annawith antihistamines, which reduces the itching sensation, but does not correct the skin le-sions.
5. What additional therapy would probably benefit this child?
A. Albuterol by inhaler
B. Topical corticosteroids
C. Epinephrine
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D. Anti-IgE
E. Cromolyn sodium
ANSWERS
1. The correct answer is D. The patient’s history suggests this is an occupational exposureto a contact allergen in solvents. The indurated nature of the lesions suggests mononu-clear cell infiltration into the skin, and the time necessary for their development (sev-eral days) is consistent with allergic contact dermatitis.
2. The correct answer is B. The standard diagnostic test for allergic contact dermatitis isthe patch test. Dilute solutions of well-standardized test allergens are available that canbe placed on the skin. It is essential that the test samples be dilute enough to not causeprimary irritant reactions on the skin.
3. The correct answer is C. This clinical picture would normally be attributed to a type Ihypersensitivity reaction mediated by IgE antibodies. However, two aspects of his reac-tion suggest this is not the pathogenic mechanism. First, he did not test positive to theallergen in an immediate-type skin test. Second, his complement levels were decreased,suggesting the activation and depletion of complement by circulating antigen–antibodycomplexes. It should also be noted that his symptoms did not appear immediately.
4. The correct answer is A. Albuterol is a β2-receptor agonist and is used as a bronchodila-tor in asthma. It acts by antagonizing histamine-induced signaling in the lung. Jesse’spulmonary dysfunction results from his lungs being hyperinflated. In addition, hisbreathing is impaired by bronchoconstriction and mucus plugging.
5. The correct answer is B. The time to onset of symptoms and the indurated nature ofthe lesions suggest this is a case of poison ivy rash. Corticosteroids are administeredtopically to inhibit macrophage and lymphocyte activation in the skin, which are twofeatures of delayed-type contact dermatitis.
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I. Only a subset of the immune responses we make to microbes isprotective. A. Neutralizing antibodies are very effective at controlling infectious agents and
limiting the effects of their toxins. 1. Antibodies can prevent viral entry into and uncoating within host cells.2. Neutralizing antibodies against microbial exotoxins (eg, tetanus toxin) block
toxin binding to host cells. 3. Seroconversion refers to the appearance of antibodies to a microbial pathogen
in a patient.a. Seroconversion can aid in the diagnosis of a specific infectious disease.b. Alternatively, seropositivity may simply indicate a prior encounter with the
organism (or a cross-reacting species), rather than an ongoing or recent in-fection.
B. The clearance of extracellular microbes is primarily mediated by opsonophagocy-tosis.1. Opsonins include antibodies, complement peptides, and soluble pattern recog-
nition molecules (Chapter 1).2. Opsonic receptors also initiate microbial killing mechanisms.
C. Killing of microbes can occur either outside or inside immune cells.1. Extracellular pathogens that are small enough to be phagocytized (eg, bacteria)
are killed within phagocytic cells.2. Large extracelluar pathogens (eg, filamentous fungi) are killed when phagocytes
adhere to the surface of the microbe. D. The resolution of an infection requires the complete eradication of the infectious
agent.1. Patients with underlying cellular immune defects often do not resolve infec-
tions well. 2. Infections often reappear in these patients after antimicrobial therapy is discon-
tinued.3. Unresolved infections can also persist in normal individuals if the microbe (eg,
Mycobacterium tuberculosis) establishes a latent infection. E. Innate and adaptive immunity provide distinct forms of protection.
1. Innate immunity to microbes is essential early in an infection and lowers theearly microbial burden in the host.
NC H A P T E R 1 4C H A P T E R 1 4
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2. Innate immunity is more important in immunologically naive hosts (eg,neonates) who lack adaptive immunity to the pathogen.
3. Adaptive immunity arises late in primary infections and often mediates resolu-tion of infections.
4. Adaptive immunity can mediate lifelong specific protection against a particularpathogen.
5. Adaptive immunity is the objective of our current vaccines.
WORLDWIDE INFECTION RATES
• Each year infectious diseases account for one-third of all deaths worldwide.
• Infectious diseases that are prevalent in developing countries are often not common in the UnitedStates.
• For example, tens of millions of individuals worldwide have schistosomiasis, leishmaniasis, and tuber-culosis.
• Malaria, tuberculosis, and AIDS each causes several million deaths each year.
• Because of the complexity of these organisms and the relatively low level of research on thesepathogens, effective vaccines have been slow to emerge.
II. The specific protective immune response to a microbial pathogendepends on the life-style of the microorganism (Tables 14–1 and 14–2). A. Protection against extracellular pathogens (eg, most bacteria) requires killing of
the microbe within an intracellular organelle by phagocytic cells.B. Large extracellular pathogens (eg, filamentous fungi) are killed when phagocytes
direct these antimicrobial responses to the extracellular environment.C. Protective responses to obligate intracellular microbes limit microbial replica-
tion or kill the infected cell as a means of destroying the microbe.D. While in the extracellular phase of their life cycle, obligate and facultative intra-
cellular microbes can be neutralized and cleared from the host by antibodies andcomplement.
III. At least eight distinct immune mechanisms are known to provideprotection against microbial pathogens.A. Membrane lysis is most effective against microbes with outer membranes (eg,
gram-negative bacteria) or lipid envelopes (eg, enveloped viruses).1. Among the gram-negative bacteria, Neisseria species are among the most sus-
ceptible to complement-mediated membrane attack.2. Antimicrobial peptides appear to act by damaging the outer membranes of
bacteria.B. Opsonophagocytosis is primarily directed at extracellular bacteria, fungi, and
parasites.1. Most opsonic receptors signal phagocytes for increased antimicrobial activity.2. Pyogenic bacteria are particularly susceptible to opsonophagocytic clearance
and killing.C. Microbial killing by neutrophils is essential for elimination of extracellular mi-
crobes.
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Table 14–1. Protective immune responses to infectious agents.a
Protective Mechanisms Immune Components Groups of Pathogens Specific Pathogens
Membrane attack Defensins, cathelicidins Gram-negative bacteria Pseudomonas aeruginosa Complement Neisseria species
Opsonophagocytosis Neutrophils, Extracellular Staphylococcus, Strepto-macrophages pyogenic bacteria coccus, Pseudomonas
Opsonic receptors and yeasts species(CR3, FcR) and ligands (iC3b, IgG)
Intracellular killing Phagolysosomes; Extracellular bacteria Many catalase-negative reactive oxygen and yeasts bacteria and fungi
Toxin neutralization IgM, IgG, IgA antibodies Exotoxin-producing Clostridium tetani, Immune complex microbes Staphylococcus aureus,
clearance Escherichia coli
Virus neutralization IgM, IgG, IgA antibodies Respiratory and Rhinoviruses, aden-Phagocytic cells, mucus gastrointestinal viruses oviruses, rotaviruses
Extracellular killing Neutrophils, Filamentous fungi, Histoplasma capsulatum, macrophages parasites Candida albicans
Macrophage-mediated Th1 cells, NK cells, Obligate or facultative Mycobacterium tuberculo-intracellular killing IFN-γ, nitric oxide intracellular pathogens sis, Listeria monocytogenes,
Candida albicans, Histo-plasma capsulatum
Cytotoxic T cell killing CD8+ T cells, MHC Viruses and many Herpes simplex virus, class I, CD4+ Th cells, intracellular bacteria Listeria monocytogenesand IL-2 and fungi
Eosinophil-mediated Eosinophils, IgE Intestinal parasites Taenia saginatacytotoxicity antibodies, FcεR (helminths)
Inhibition of intracellular Type I interferons Most viruses Herpesvirusesreplication
NK cell-mediated NK cells, MHC class I Many viruses Herpesvirusescytotoxicity
aIg, immunoglobulin; NK, natural killer; IFN, interferon; MHC, major histocompatibility complex.
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1. Reactive oxygen species (eg, hydrogen peroxide) mediate killing of many aer-obic microbes.
2. A more limited range of microbes (eg, Lysteria, Mycobacterium species) is killedby reactive nitrogen species (eg, nitric oxide).
3. For the killing of anaerobic microbes, oxidants are less important than antimi-crobial peptides and lysosomal hydrolases.
D. Intracellular microbes (eg, Mycobacterium, Legionella, Listeria, Salmonella, andFrancisella species) that replicate within mononuclear phagocytes are particularlysusceptible to Th1-type cellular immunity.1. Macrophage activation by Th1 cytokines is a key step.2. A combination of reactive oxygen and nitrogen metabolites and oxygen-inde-
pendent mediators mediates killing.E. Toxin neutralization is important in decreasing the severity of infectious diseases
mediated by endo- and exotoxins. F. Virus neutralization is particularly important in blocking virus attachment to
mucosal surfaces and in clearing viruses from the blood stream.1. Secretory immunoglobulin (Ig) A antibodies protect against inhaled and in-
gested viruses.2. IgG antibodies reduce viremia and block virus spread.3. Antibodies are particularly important for viruses (eg, rabies, polio) that require
hematogenous dissemination.
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Table 14–2. Important protective immune components organized by microbe class.a
Immune Extracellular Intracellular Component Bacteria Bacteria Viruses Fungi Parasites
Antibody ++ Minimal ++ − ++
Complement ++ Minimal + − −(enveloped)
Neutrophils ++ − or + − + −(eosinophils)
Th2 cells ++ − ++ − −
Th1 cells − ++ ++ ++ ++
Macrophages + ++ + ++ ++
Cytotoxic T cells − + ++ − −
NK cells ++ + + Unknown Unknown(cytokines) (cytokines) (lysis)
aNK, natural killer.
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G. Cytotoxic T cells (CTL) provide protection against intracellular pathogens whoseantigens are presented by major histocompatibility complex (MHC) class I mole-cules. 1. Most virus-infected cells are susceptible to CTL attack. 2. Microbes that block the class I pathway of antigen presentation (eg, herpes-
viruses) can evade CTL-mediated clearance.3. Intracellular bacteria that escape the phagosome (eg, Listeria, Francisella) are
also subject to detection by CTL.H. Natural killer (NK) cells also protect against pathogen-infected host cells.
1. NK cells can recognize and kill infected host cells in which the microbe has in-hibited MHC class I expression.
2. NK cells produce type I interferons (IFN-α, β) early in infection. a. IFN-α, β establishes an antiviral state within infected cells.b. IFN-α, β induces RNase L and protein kinase R, which degrade viral
mRNA and block translation, respectively. I. Eosinophils use IgE antibodies to attack extracellular parasites (eg, intestinal
worms) by antibody-dependent cellular cytotoxicity (ADCC).
III. The nature of opportunistic infections in immunocompromised patientscan reveal important protective immune responses (Table 14–3).A. Infections with intracellular pathogens are common in patients lacking Th1 cell,
CTL, NK cell, or macrophage functions.B. Microbes that replicate within the cytosol (eg, viruses) are particularly problematic
for patients with CTL or MHC class I defects.
Table 14–3. Common infections in the immunocompromised patient.a
T Cells B Cells Phagocytic Cells Complement
Bacteria Mycobacterium, Stahpylococcus, Staphylococcus, Staphylococcus, Listeria Streptococcus, Streptococcus, Streptococcus,
Haemophilus Haemophilus Neisseria
Fungi Candida, Aspergillus, CandidaHistoplasma, Pneumocystis
Viruses CMV, HSV, Enteroviruses, VZV, EBV, JC influenza, RSV
Principal Macrophage, Virus neutrali- Phagocytosis, Membrane attack, mechanisms NK cell, and zation, opsono- intracellular killing chemotaxis and
CTL activation phagocytosis opsonophagocytosis
aCMV, cytomegalovirus; HSV, herpes simplex virus; VZV, varicella-zoster virus; EBV, Epstein–Barr virus; RSV, respiratorysyncytial virus; NK, natural killer; CTL, cytotoxic T cell.
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C. Opportunistic infections with extracellular bacteria (eg, Staphylococcus aureus) andsome cytolytic viruses (eg, influenza viruses) are common in antibody-deficiencystates.
D. Extracellular bacteria and fungi commonly infect patients with neutrophil de-fects, including deficiencies in oxidant production or granule expression.
E. Patients with complement deficiencies cannot lyse gram-negative bacteria and en-veloped viruses or clear extracellular microbes.
IV. Microbial immune evasion mechanisms have evolved to circumvent themost important protective responses by the host.A. Antigenic variation allows bacteria, viruses, and parasites to avoid immune recog-
nition. 1. Point mutations in antigenic proteins (antigenic drift) occur in influenza and
human immunodeficiency virus (HIV)-1 by error-prone nucleic acid replica-tion.
2. Other organisms, including Neisseria gonorrhea and Trypanosoma cruzii, scram-ble the genes that encode their major surface antigens.
3. More substantial changes in antigens (antigenic shift) occur by genetic recom-bination between related viruses.
B. Adopting an intracellular life cycle is a microbial response to immune elimina-tion mediated by antibody and complement.1. The host response to this microbial strategy has been to evolve CTL and NK
cells capable of recognizing a microbe-infected cell.2. Antigen presentation can be viewed as a host adaptation to intracellular micro-
bial parasitism.C. Disguising microbial antigens prevents immune recognition and attack.
1. Schistosomes coat themselves with host MHC molecules.2. Plasmodium species (etiological agents of malaria) infect erythrocytes that do
not express MHC molecules.3. Many bacteria (eg, Streptococcus pneumoniae and Haemophilus influenzae) ex-
press thick polysaccharide capsules that disguise their more antigenic cell wallcomponents.
4. The long polysaccharide chains of bacterial lipopolysaccharide (LPS) moleculesdirect complement activation away from the bacterial outer membrane.
ANTIGENIC SHIFT IN THE INFLUENZA A VIRUS
• The influenza A virus is responsible for periodic worldwide pandemics.
• Protective immunity to this virus depends on the production of neutralizing antibodies to two surfaceglycoproteins, neuraminidase (N) and hemagglutinin (H).
• Antigenic drift is the gradual change in the N and H serotypes by mutation.
• Regular monitoring of the N and H gene sequences determines the serotype of the predominant in-fluenza virus each flu season, and an appropriate vaccine is produced.
• Occasionally, a major antigenic shift occurs due to reassortment of genomes between different in-fluenza virus strains, including those of animals.
• The 1957 “Asian flu” pandemic resulted from the sudden emergence of new H and N serotypes by ge-netic reassortment between antigenically distinct influenza viruses.
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D. Suppression of the immune response is another common approach to evasion.1. HIV-1 infects and depletes CD4+ T cells. 2. Herpesviruses, HIV-1, and adenoviruses inhibit MHC expression or trans-
porter associated with antigen processing (TAP) function and thereby depressCTL activation.
3. Many viruses produce proteins that mimic inhibitory cytokines or bind to acti-vating cytokines (eg, Epstein–Barr virus and poxviruses, respectively).
4. Protein A produced by staphylococci binds IgG Fc regions. 5. Streptococcus pyogenes produces a C5a peptidase.6. N gonorrhea produces a protease that degrades secretory IgA.7. Legionella and Listeria species avoid intracellular killing by blocking phago-
some–lysosome fusion or escaping from the phagosome, respectively.
V. Effective vaccines augment protective host responses to infection. A. Vaccines do not typically prevent infections, although they reduce the severity of
infectious diseases.B. Most existing vaccines are preemptive; they must be given prior to infection
(Table 14–4).
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Table 14–4. Recommended immunizations for children.a
aAdapted from www.cdc.gov/nip/recs/child-schedule.htm#printable. The different shades denote the different number ofimmunizations (eg, children should receive three immunizations with the hepatitis B vaccine).
1 2 4 6 12 15 18 24 4–6Birth mo mo mo mo mo mo mo mo yr
Vaccine
Hepatitis B
Diphtheria, tetanus, pertussis
Haemophilus influenzaetype b
Inactivated poliovirus
Measles, mumps, rubella
Varicella
Pneumococcal conjugate
Influenza Annual
Hepatitis A At risk At risk
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1. Only a few vaccines (eg, rabies, hepatitis) are therapeutic vaccines that can beused to treat an infected patient.
2. Rabies is a slowly progressing infection that does not outpace the immune re-sponse.
C. All existing vaccines are directed at epitopes, not microbial patterns, and induceadaptive immunity.
D. We have very few vaccines against complex microbes (eg, parasites).E. Most of our best vaccines induce neutralizing antibodies.F. Routine pediatric vaccines (Table 14–4) are designed to prevent life-threatening
infectious diseases of childhood.1. These diseases typically outpace the ability of the neonate to mount an ade-
quate protective immune response.2. Immunization is also valuable when the dose of a microbial toxin (eg, tetanus
toxin) sufficient to cause disease is far less than the immunizing dose. 3. Some vaccines (eg, H influenzae type b conjugate vaccine) are designed to elicit
opsonic IgG antibodies that would not normally be made during an infectionin children.
G. Practical issues dictate the design and use of vaccines. 1. Live attenuated vaccines can cause disease in an immunodeficient individual
and should be avoided. 2. Repeated immunizations are required to attain high-titered, long-lasting pro-
tective immunity or to compensate for antigenic shift.3. Multiple immunizations are necessary to induce Ig isotype switching (eg, IgG
antibody formation).
COMMON COLDS IN CHILDREN
• Children normally contract five or six colds (upper respiratory tract infections) each year.
• This frequency is increased by exposure to day care centers and cigarette smoke, allergies and asthma,cystic fibrosis, congenital immune defects, and ciliary dyskinesia.
• Several hundred different viruses can cause the common cold, including the rhinoviruses, influenzaviruses, adenoviruses, and respiratory syncytial virus.
• The development of a vaccine for this disease has been hampered by the wide variety of antigenicallydistinct agents responsible for these infections.
4. The design of a vaccine should theoretically reflect the principal protective re-sponse desired in the host (Table 14–5). a. Immunization against intracellular pathogens requires a live vaccine that du-
plicates the intracellular infection.b. Live attenuated vaccines are useful when inducing a CTL response. c. Polyvalent vaccines (eg, Neisseria species) are useful when multiple
serotypes of a pathogen cause disease.d. Subunit vaccines (eg, hepatitis B) are effective when inducing immunity to
surface antigens or toxins.e. Conjugate vaccines (eg, H influenzae type b) promote the production of
IgG antibodies to T-independent epitopes.f. Mucosal immunization (eg, influenza nasal vaccine) can protect against
respiratory or gastrointestinal pathogens.
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NOVEL VACCINE STRATEGIES
• Molecular biological techniques provide the means for isolating genes from microbial pathogens andexpressing them in relatively safe viral vectors.
• This permits the construction of polyvalent vaccines carrying genes for a large number of microbialantigens.
• Adjuvant activity can be included by also expressing genes for human cytokines (eg, switch cytokinesor Th1 cell-inducing cytokines) and costimulatory molecules.
• DNA vaccines are another approach that could be used to induce T cell-mediated immunity by direct-ing microbial protein expression associated with host MHC.
CLINICAL PROBLEMSA 15-month-old child is seen by his pediatrician for a cough, congestion, and fever of39°C. He has a rapid pulse, appears ill, and is unresponsive. His white blood cell count iselevated. His mother seems unsure of his immunization history, but recalls only two visitsto the county health clinic for immunizations. The pediatrician prescribes the antibioticampicillin, and the child’s condition improves substantially over the next few days.
1. A routine pediatric vaccine for which of the following pathogens might have preventedthis condition?
A. Rabies
B. Poliovirus
C. Legionella pneumophilaD. Haemophilus influenzae type b
E. Hepatitis B
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Table 14–5. Types of vaccines.
Type of Vaccine Examples
Live attenuated Oral polio, varicella; mumps, measles, rubella, bacillusCalmette–Gúerin (BCG)
Killed or inactivated Inactivated polio
Subunit Diphtheria toxoid, tetanus toxoid
Recombinant subunit Hepatitis B
Conjugate Haemophilus influenzae type b, Streptococcus pneumoniae
Polyvalent S pneumoniae
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Harry is aware that he has a congenital deficiency of the C6 complement peptide.
2. For which of the following infectious agents is Harry particularly susceptible?
A. Streptococcus pneumoniaeB. Neisseria meningitidisC. Clostridium tetaniD. Mycobacterium tuberculosisE. Clostridium difficile
Donald has a defect in his IFN-γ receptor resulting from an inherited mutation in one ofthe receptor-encoding genes.
3. Which of the following pathogens would most likely cause recurrent infections in thischild?
A. Pseudomonas aeruginosaB. Streptococcus pyogenesC. Staphylococcus aureusD. Legionella pneumophilaE. Neisseria meningitidis
A 1-day-old child born of an uncomplicated full-term pregnancy presents with jaundice.The mother is Rh+, and the newborn is not anemic. Suspecting a congenital virus infec-tion, viral serology on a sample of the child’s serum is ordered. High-titered IgG antibod-ies to cytomegalovirus are found.
4. What can be concluded from these clinical and laboratory findings?
A. The patient has a congenital cytomegalovirus (CMV) infection.
B. The infant suffers from Rh disease of the newborn.
C. The child should be immunized immediately to limit CMV infection.
D. The infant should be given broad-spectrum antibiotics.
E. The positive CMV serology reflects the immune status of the mother.
Milind is a 56-year-old immigrant from India who is brought to the emergency room witha cough that produces blood-containing sputum. He has a positive skin test with tuber-culin purified protein derivative (PPD), and his chest x-ray shows lesions typical of my-cobacterial pneumonia. He indicates that he was immunized with bacillus Calmette–Gúerin (BCG) as a child.
5. What is the nature of this vaccine?
A. Subunit vaccine
B. Conjugate vaccine
C. Live attenuated vaccine
D. Recombinant vaccine
E. Polyvalent vaccine
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ANSWERS
1. The correct answer is D. H influenzae is a gram-negative bacterium that can cause mildnasopharyngeal infections. In young children, these conditions can progress to menin-gitis, and vaccination has proven effective at reducing morbidity and mortality. Multi-ple immunizations in children are recommended by 15 months of age (Table 14–4).
2. The correct answer is B. Neisseria species are among the most susceptible to comple-ment-mediated lysis by the C5b-9 membrane attack complex due to the structure oftheir outer membranes. The other organisms listed do not have classic outer mem-branes.
3. The correct answer is D. Only Legionella pneumophila is an intracellular pathogen. De-fective IFN-γ signaling would impair Th1 cellular immunity, especially the activationof macrophages. This bacterium establishes an intracellular infection within restingmacrophages and is killed when macrophages become activated.
4. The correct answer is E. High-titered antibodies to CMV in a newborn’s serum mostlikely reflect IgG that has crossed the placenta from the mother. Vaccinating the childat this point would not limit the infection, and there currently is no CMV vaccine.
5. The correct answer is C. The BCG strain is a live bovine mycobacterium that inducescross-protective immunity to other Mycobacterium species in humans. Its effectivenessderives from its ability to establish life-long Th1-type cellular immunity against my-cobacterial antigens, but protection is variable among vaccines.
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I. Primary immune deficiency diseases in human beings are generally rare,inherited conditions affecting a defined immune component (Figure 15–1and Table 15–1).A. The term congenital is also used to describe these diseases, because they are in-
herited and become apparent early in life.B. Recurrent infections are the most common clinical presentation.
1. The nature of the infections in an immunocompromised patient can provideimportant clues for establishing a diagnosis. a. These infections are often with opportunistic pathogens, which do not
pose problems for healthy individuals.(1) Opportunistic agents generally show low virulence.(2) Many opportunistic microbes are normal flora.
b. The infections may resist aggressive antimicrobial therapy or may not re-solve (Chapter 14) after the completion of the therapy.
c. The infection may progress more rapidly than it would in an immuno-competent individual of the same age.
d. The course of the infections may be unusual in severity or organ involve-ment.
e. The infections may occur much earlier in life (eg, during the first week)than would be seen in a normal child.
f. The infections may show delayed onset in infancy (eg, after 6 months oflife), reflecting the normal decline of maternal antibody acquired duringpregnancy.
g. Similar infections may have occurred within a family, especially amongmale infants.
h. The infections may follow shortly after immunization with a live vaccine.2. In adults, recurrent infections more often indicate an acquired or secondary
immune deficiency.a. A history of high risk behavior for human immunodeficiency virus
(HIV)-1 infection (intravenous drug abuse, unprotected sex with an in-fected partner) supports a diagnosis of an acquired immune deficiency.
b. Chemotherapy for cancer or occupational exposure to ionizing radiationincreases the risk of immunodeficiency.
c. Patients who are receiving immunosuppressive therapy for autoimmunedisease or following transplantation are at risk for recurrent infections.
NC H A P T E R 1 5C H A P T E R 1 5
IMMUNE DEFICIENCYSTATES
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Neutrophils Monocytes
Lymphoid progenitor cell
Mature T cellMature B cell
Memory B cell
Pre-B cell Pre-T cell
Plasma cell
Stem cell
Myeloid progenitor cell
Congential agranulocytosis
Chronicgranulomatousdisease
Leukocyte-adhesion defect
Wiskott-Aldrich syndrome
X-linked hyper-IgM syndrome
Selective immunoglobulin deficiencies
Common variable hypogammaglobulinemia
X-linked agammaglobulinemia
X-linked agammaglobulinemia
Severe combinedimmunodeficiency(SCID):γc deficiency
Severe combined immunodeficiency: Rag deficiency
Thymus
DiGeorgesyndrome
Bare-lymphocytesyndrome
Figure 15–1. Primary immune deficiencies.
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3. Conversely, the successful resolution of an infection aids in establishing a dif-ferential diagnosis of immune deficiency diseases.a. Children who resolve a viral infection (eg, chickenpox) in a normal manner
are not likely to be deficient in T cells.b. Patients who do not have a history of recurrent bacterial infections proba-
bly have normal neutrophil function.
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Table 15–1. Examples of selective primary T and B cell deficiencies.a
Category Molecular or Clinical of Deficiency Examples Cellular Defect Presentation Therapies
Antibody or XID Btk kinase Infections with Antibiotics, IVIGhumoral immunity mutation extracellular
bacteria commenc-ing at 6–9 months of age
Selective IgA Varied Sinopulmonary in- Antibioticsdeficiency fections and
diarrhea; increased incidence of ato-pic allergies
Hyper-IgM CD154 or AID Elevated IgM; little or Antibiotics, IVIGsyndrome mutations no IgG or IgA;
absence of Ig class switching; bacterial infections
T cell or cellular DiGeorge Thymic Parathyroid defi- Antimicrobial agents; immunity syndrome epithelium ciency; heart thymic transplant
defects; early onset of fungal and viral infec-tions; lymphopenia
BLS-II Transcription of Absence of HLA-D Antimicrobial agents; HLA class II expression; oppor- stem cell transplantgenes tunistic viral and
fungal infections; CD4+ T cell lymphopenia
Deficiency ZAP-70 Recurrent viral and Antimicrobial agents; of TCR mutation fungal infections; stem cell transplantsignaling depressed cellular
immunity
aXID, X-linked immunodeficiency; Btk, Bruton’s tyrosine kinase; Ig, immunoglobulin; IVIG, intravenous immunoglobulin;AID, activation-induced cytidine deaminase; BLS-II, bare lymphocyte syndrome type II; TCR, T cell receptor; ZAP-70, ζ-associated protein-70.
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4. The nature of the infectious agent can suggest the type of selective immunedeficiency. a. Patients with primary antibody, phagocytic cell, or complement deficien-
cies present with recurrent infections involving extracellular bacteria andcertain fungi.
b. Patients with primary T cell or combined [T cell plus antibody and/or nat-ural killer (NK) cell] immune deficiencies present with recurrent infectionsinvolving viruses, intracellular bacteria, fungi, and certain parasites.
C. A differential diagnosis is essential for determining appropriate therapy.1. Antibody, phagocytic cell, and complement deficiencies present with similar
types of infections, but require distinct therapies. 2. Similarly, deficiencies in recombination activating gene 1 (Rag1), transporter
associated with antigen processing (TAP)-1, and thymus development presentwith similar opportunistic virus infections.
II. Antibody deficiencies are the most common immune deficiency state ininfants and children, accounting for nearly half of all conditions (Table15–2).A. The prevalence of these diseases ranges from a few reported cases to 1 case per
350 individuals.B. Antibody deficiencies range from generalized agammaglobulinemia to selective
immunoglobulin (Ig) (sub)class deficiencies (eg, IgG2 deficiency). C. Some patients with normal serum levels of Igs fail to make antibodies to impor-
tant microbial antigens.D. The most frequent antibody deficiencies represent a failure to synthesize or se-
crete Ig, rather than an absence of B cells.1. Selective IgA deficiency is the most common primary immune deficiency
with a frequency of 1 in 350.a. In some patients, IgA is synthesized but not secreted.
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Table 15–2. Distinguishing features of primary antibody deficiencies.a
Disease Distinguishing Features
Selective IgA deficiency Most common primary immune deficiency; many affectedindividuals are asymptomatic; IVIG contraindicated
Selective IgG2 deficiency Impaired antibody responses to bacterial polysaccharideantigens; recurrent infections with encapsulated bacteria
Transient hypogamma- Delayed onset of IgM and IgG production; IVIG con-globulinemia of infancy traindicated; recurrent sinopulmonary infections
XLA Absence of peripheral CD19+ B cells; delayed onset to 6months of age; X-linked; pyogenic bacterial infections
aIg, immunoglobulin; IVIG, intravenous immunoglobulin; XLA, X-linked agammaglobulinemia.
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b. Nearly half of IgA-deficient patients are asymptomatic due to the transloca-tion of IgM across the mucosal epithelium.
2. Selective IgG2 deficiency is a common form of IgG deficiency.a. These patients do not respond to polysaccharide vaccines.b. Infections with encapsulated bacteria are common.
3. Transient hypogammaglobulinemia of infancy is a condition that can leadto infections toward the end of the first year of life.a. These infants have normal numbers of mature B cells.b. They show delayed IgG secretion that becomes apparent as maternal IgG
levels subside (ie, at 6–8 months of age). c. Otitis media, pneumonia, and diarrhea are common.
E. B cells are absent in only a few antibody deficiency diseases.1. X-linked agammaglobulinemia (XLA) is a mutation in the gene for Bruton’s
tyrosine kinase (Btk).a. B cell development is blocked at the pre-B cell stage.b. XLA patients have a peripheral phenotype of T+B−NK+.c. Normal levels of serum IgG are present at birth and wane over time. d. XLA patients suffer from recurrent infections with pyogenic (pus-forming)
extracellular bacteria.2. A similar phenotype is seen in patients with Ig H chain locus deletions that
prevent the expression of a functional µ chain.3. Igα deficiency blocks B cell development at the pre-B stage.4. κ-chain deficiency blocks the differentiation of κ-bearing B cells.
F. Most antibody deficiencies can be diagnosed using simple laboratory tests.1. Except for certain rare conditions (eg, XLA), the measurement of B cell num-
bers is not essential to establishing a diagnosis.2. Ig concentrations can be measured by nephelometry (Chapter 5). 3. Isohemagglutinin titers reflect the ability to produce antibody. 4. Responses to the tetanus toxoid and pneumococcal polysaccharide vaccines
provide information on memory and naive B cell function.5. A differential diagnosis requires the elimination of phagocytic cell and com-
plement deficiencies.G. The treatment of B cell deficiencies addresses both infections and the underlying
hypogammaglobulinemia.1. Antibiotics are given to treat bacterial infections.2. Intravenous immunoglobulins (IVIG) restore antibody levels.
a. Because the half-life of IgG is approximately 3 weeks, IVIG must be givenfrequently.
b. IVIG is prepared from the pooled sera of immune donors. c. IVIG therapy is not recommended for children with transient hypogamma-
globulinemia of infancy or patients with selective IgA deficiency.3. Because IVIG is relatively safe and effective, stem cell transplantation is rarely
performed to correct B cell deficiencies.
IVIG AND SELECTIVE IGA DEFICIENCY
• Selective IgA deficiency is an important exception to the general use of IVIG to treat antibody deficien-cies.
• The use of IVIG in these patients carries a risk of anaphylactic or anaphylactoid shock.
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• This is thought to result from the tendency of these patients to produce IgE and IgG antibodies to IgAthat is present in the IVIG preparations.
• Such antibodies mediate type I and type III hypersensitivity responses to IVIG.
III. Patients with primary T cell (T−B+NK+) and combined (T−B−NK+, T−
B+NK−, or T−B−NK−) immune deficiencies acquire infections in their firstfew weeks of life.A. These infections are pediatric emergencies.
1. The infectious agents include viruses, fungi, and other intracellularpathogens.
2. Many of the organisms that infect T cell-deficient patients (eg, Cryptosporid-ium, Pneumocystis, Leishmania species) show low virulence and only rarelycause disease in the general population.
3. The infections in T cell-deficient patients are often disseminated and rapidlyprogressing.
GRAFT-VERSUS-HOST DISEASE (GVHD) IN PREGNANCY
• GVHD is typically seen only in stem cell transplantation (Chapter 17).
• T cells of the donor recognize and attack the recipient’s tissues.
• Because pregnancy provides an opportunity for maternal T cells to recognize fetal HLA antigens inher-ited from the father, GVHD can also occur in this setting.
• Because the fetal immune system is sufficiently mature to destroy maternal T cells that cross the pla-centa, the disease is rarely seen in normal pregnancies.
• However, when fetuses have congenital T cell deficiencies, GVHD can occur.
• GVHD also occurs when fresh whole blood is transfused to a T cell-deficient child.
B. Selective T cell deficiencies are due to blocks in thymocyte differentiation and/orreceptor-initiated cell signaling (Table 15–3).1. DiGeorge syndrome is a rare thymic hypoplasia due to dysmorphogenesis of
the third and fourth pharyngeal pouches.a. Embryonic abnormalities are also seen in the heart, major vessels, parathy-
roid, and facial structures.b. Antibody deficiency results from the absence of Th cells.c. T cell lymphopenia and opportunisitic viral and fungal (eg, Pneumocystis)
infections result.2. Defects in T cell receptor (TCR)-initiated signaling (Chapter 6) cause defi-
ciencies in cell-mediated immunity.a. Loss-of-function mutations exist in CD3ζ, Lck, and ζ-associated protein-
70 (ZAP-70).b. Defective positive selection in the thymus causes peripheral lymphopenia
with a T−B+NK+ phenotype.3. Bare lymphocyte syndrome type I (BLS-I) is a selective deficiency of CD8+
T cells.a. This condition is caused by mutations in the TAP proteins.b. Major histocompatibility complex (MHC) class I expression and posi-
tive selection in the thymus are impaired.c. The peripheral lymphocyte phenotype is CD4+CD8−B+NK+.
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4. Bare lymphocyte syndrome type II (BLS-II) results in a CD4−CD8+B+NK+
phenotype.a. These patients have mutations in transcription factors, such as CIITA, that
coordinately regulate MHC class II gene expression.b. Positive selection of CD4+ thymocytes is impaired.c. The activation of peripheral CD4+ T cells is blocked.
5. A family of related Th 1 cell deficiencies is caused by deficient cytokine sig-naling.a. Interleukin (IL)-12 and IL-12 receptor defects block Th1 cell differentia-
tion and activation.b. Interferon (IFN)-γ receptor deficiency blocks macrophage activation.c. Recurrent infections with intracellular bacteria (eg, Mycobacterium and Sal-
monella species) result. 6. The absence of the coreceptor CD40 or its ligand, CD154, causes hyper-IgM
syndrome type 1.a. This leads to a deficiency of the Th2 signals necessary for Ig class switching
in B cells (Chapter 6).b. Patients have elevated levels of IgM antibodies, but no IgG, IgA, or IgE.
7. Hyper-IgM syndrome type 2 results from a mutation in the gene for activa-tion-induced cytidine deaminase (AID) (Chapter 9).
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Table 15–3. Distinguishing features of primary T cell deficiencies.a
Disease Distinguishing Features
DiGeorge syndrome Lymphopenia with hypoparathyroidism, cardiac and facialdefects; corrected by thymic transplant
ZAP-70 or CD3ζ Absence of both CD4+ and CD8+ T cell function with nor-deficiency mal numbers of B cells and NK cells
BLS type I Absence of HLA class I expression and decreased numbersof CD8+ T cells
BLS type II Absence of HLA class II expression and decreased numbersof CD4+ T cells
Th1 deficiency Decreased IL-12 and IFN-γ signaling; mycobacterial pneumo-nia
Hyper-IgM syndrome Absence of CD154; elevated IgM antibody responses; type 1 decreased IgG and IgA
AID deficiency Elevated IgM antibody responses; normal expression ofCD154 and CD40
aZAP-70, ζ-associated protein-70; NK, natural killer; BLS, bare lymphocyte syndrome; IL, interleukin;IFN, interferon; Ig, immunoglobulin; AID, activation-induced cytidine deaminase.
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a. T helper cell signaling for Ig class switching is absent. b. Somatic hypermutation and affinity maturation in B cells are also im-
paired. C. Severe combined immune deficiency (SCID) is caused by a number of differ-
ent genetic mutations (Table 15–4).1. The X-linked recessive form of SCID is most prevalent.
a. It is caused by an absence of the common γ chain (γc) of the receptors forIL-2, IL-4, IL-7, IL-9, and IL-15.
b. Abnormal development of T cells and NK cells results in a T−B+NK− phe-notype.
2. The same phenotype (T−B+NK−) is seen in deficiencies of Janus kinase 3(Jak3), which mediates signaling from these receptors.
3. Mutations in the gene coding for the enzyme adenosine deaminase (ADA)cause SCID.a. ADA catalyzes the breakdown of intracellular adenosine and deoxyadeno-
sine.b. Excess adenosine inhibits methyltransferase reactions in T cells, B cells, and
NK cells resulting in a T−B−NK− phenotype.4. Mutations in the Rag1 and recombination activating gene 2 (Rag2) genes
block T and B cell development by preventing TCR and B cell receptor(BCR) gene rearrangements. a. Lymphocyte differentiation is blocked at the pre-T and pre-B cell stages.b. The lymphocyte phenotype in this condition is T−B−NK+.
5. Wiscott–Aldrich syndrome (WAS) is a condition characterized by thrombo-cytopenia and immune deficiency.
6. Perforin and granzyme deficiencies manifest as decreased T cell and NK cellcytotoxic activity.
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Table 15–4. Distinguishing features of primary SCID.a
Overall Cellular Gene Mutation Phenotype Distinguishing Features
γc T−B+NK− Most frequent cause; impaired signaling throughmultiple cytokine receptors; normal B cell num-bers
Jak3 T−B+NK− Rare, but otherwise indistinguishable from γcdeficiency
ADA T−B−NK− Decline in the numbers of all lymphocyte sub-sets over time
Rag1, Rag2 T−B−NK+ Absence of peripheral T and B cells from birth;normal NK cells
aJak3, Janus kinase 3; ADA, adenosine deaminase; Rag1, Rag2, recombination activating genes 1 and 2;NK, natural killer.
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D. The diagnosis of T cell and combined immune deficiencies depends on recog-nizing the typical infections that characterize these conditions and measuringlymphocyte numbers and functions.1. Infections begin in the first few months of life. 2. Lymphopenia is common.3. Measuring anti-HIV antibodies or viral load is essential when a T cell defi-
ciency is suspected.4. Measuring CD3, CD4, CD8, CD19, and CD154 expression by flow cytome-
try can help detect lymphocyte subset deficiencies.5. T cell proliferation in response to polyclonal activators (the plant mitogen
phytohemagglutinin) can be measured in vitro.6. Delayed-type hypersensitivity (DTH) skin tests (eg, intradermal or patch test-
ing) are used to evaluate CD4+ Th1 cell responses to common microbes. E. Therapy includes antiviral and antifungal agents and hematopoietic stem cell re-
placement.1. Thymus transplantation is effective in treating DiGeorge syndrome.2. Stem cell transplantation (Chapter 17) is effective for SCID and selective T
cell deficiency patients.3. Gene therapy is being tested for some of these immune deficiencies (eg, ADA
deficiency).4. Other therapies are contraindicated.
a. T cell-deficient patients should not be immunized with live viral vaccines.b. All blood products (whole blood, platelets, and plasma) should be irradi-
ated prior to transfusion.
GENE THERAPY FOR IMMUNE DEFICIENCIES
• The identification of specific genetic mutations that cause immunodeficiency diseases provides the op-portunity to correct these conditions by gene therapy.
• The most promising approach appears to be “repairing” the defective gene within the patient’s ownhematopoietic stem cells by retroviral transfer followed by reinfusion.
• ADA deficiency was the first human disease treated by gene therapy in the 1990s.
• Other immune deficiencies that have been considered include γc deficiency, leukocyte adhesion defect(LAD; CD18 deficiency), and chronic granulomatous disease (respiratory burst deficiency).
IV. Primary phagocytic cell deficiencies result from decreased cell number,abnormal cell adhesion and migration, defective intracellular granules, orimpaired intracellular killing mechanisms (Table 15–5).A. Cyclic neutropenia is caused by a mutation in the neutrophil elastase gene.
1. Neutropenia (< 200 cells/µL) occurs periodically. 2. Treatment with recombinant colony-stimulating factor-granulocyte (CSF-G)
has proven effective. B. LAD is characterized by poor leukocyte adhesion to the vascular endothelium, de-
layed wound healing, and defective complement-dependent opsonophagocytosis.1. LAD type 1 is a mutation in the gene for CD18, a β2 integrin family mem-
ber (Chapter 8). a. Patients show chronic leukocytosis involving neutrophils and fail to phago-
cytize iC3b-coated particles.
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b. Diagnosis is aided by demonstrating the absence of CD11 or CD18 onblood leukocytes.
2. LAD type 2 is a defect in fucose metabolism that impairs selectin function.3. LAD type 3 is a defect in selectin expression.4. LAD type 4 is caused by a mutation in the rac signaling molecule activated by
CD18.C. Chediak–Higashi syndrome (CHS) results from the excessive fusion of granules
in a number of granulated cells, including leukocytes. 1. The defect is caused by a mutation in a regulator of lysosomal trafficking. 2. CHS cells show poor chemotaxis and impaired NK cell function.
D. Neutrophil-specific granule deficiencies, including the absence of α and β de-fensins, result in impaired intracellular killing of microbes.
IMMUNE DEFICIENCY IN JOB’S SYNDROME
• Job’s syndrome (hyper-IgE syndrome; Chapter 13) is characterized by highly elevated levels of serumIgE, eczema, and sinopulmonary and skin infections.
• Given the elevated IgE levels, atopic dermatitis is a common misdiagnosis.
• Infections can cause deep skin and lung abscesses.
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CLINICALCORRELATION
Table 15–5. Distinguishing features of phagocytic cell deficiencies.a
Disease Distinguishing Features
Cyclic neutropenia Oscillating neutropenia; responsiveness to CSF-G
LAD type 1 Chronic leukocytosis; absence of CD18-containing re-ceptors; limited neutrophil extravasation and pus for-mation; impaired iC3b-mediated phagocytosis
LAD type 2 Leukocytosis; infections; normal CD18
LAD type 3 Decreased selectin expression
LAD type 4 Impaired CD18 initiated signaling
Chediak–Higashi syndrome Formation of giant fused granules in neutrophils andNK cells
CGD Absence of superoxide production; infections withcatalase-positive microbes; granulomas
Job’s syndrome Decreased IFN-� synthesis; IgE levels, skin abscesseswithout erythema or tenderness
Th1 pathway defects Impaired macrophage activation
aCSF-G, colony-stimulating factor-granulocyte; IFN, interferon; LAD, leukocyte adhesion defect; NK,natural killer; CGD, chronic granulomatous disease.
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• An unusual characteristic of the skin lesions is the absence of erythema, tenderness, and warmth, simi-lar to the appearance of the skin boils of the biblical character Job.
• A marked decrease of IFN-γ production by these patients may explain both the elevated IgE levels andthe impaired phagocyte responses to infection.
E. Chronic granulomatous disease (CGD) is a heterogeneous condition caused bya defective respiratory burst oxidase.1. Mutations in any of four subunit genes have been reported.2. Diagnosis is based on the nitroblue tetrazolium (NBT) dye reduction test for
oxidant production. 3. CGD is characterized by bacterial and fungal infections, especially Staphylo-
coccus and Aspergillus species.4. Granulomas form in the lungs, liver, and spleen when microbes that cannot
be killed are “walled off.” 5. Prophylactic antibiotics, recombinant IFN-γ, and granulocyte transfusions are
beneficial.6. Stem cell transplantation is potentially curative.
F. Myeloperoxidase (MPO) deficiency causes a block in the production of hypo-halous acids.
G. Aggressive treatment with antibiotics is necessary to control infections in phago-cytic cell deficiencies.1. Some conditions benefit from prophylactic antimicrobial agents.2. Recombinant cytokines are of value in treating cyclic neutropenia and CGD.3. Leukocyte transfusions during acute infections are beneficial. 4. Stem cell transplantation is potentially curative in CGD, Chediak–Higashi
syndrome, and LAD.
ANTIBIOTICS AND PHAGOCYTE DEFICIENCIES
• Neutrophil deficiencies tend to manifest as gingivitis and periodontal diseases, cutaneous infectionsand abscesses, pneumonias, and/or granulomas caused by multiple infectious agents.
• While IFN-γ deficiency affects macrophage function and results in infections primarily with intracellu-lar bacterial pathogens, diverse types of pathogens cause infections in Chediak–Higashi syndrome orcyclic neutropenia.
• Prophylactic antimicrobial therapy is less effective when infections are caused by diverse microbialspecies.
V. Inherited deficiencies in the complement system cause both infectious andnoninfectious diseases (Table 15–6).A. Rare deficiencies in all of the individual components have been described.
1. A deficiency of mannose-binding protein (MBP) is the most common singlecomponent defect.
2. C2 deficiency is the most common deficiency affecting the classical pathway.B. Deficiencies in the classical, lectin, or alternative pathways can increase the sus-
ceptibility to bacterial and some viral infections.1. Early pathway deficiencies result in recurrent pyogenic infections.2. Defects in the terminal components C5–C8 lead to disseminated Neisseria in-
fections.
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C. Defects in the expression of the complement regulatory components causeboth infectious and noninfectious diseases.1. Factor I deficiency increases the risk of pyogenic infections, including
meningococcal meningitis. a. Unrestrained complement activation leads to C3 consumption (Chapter 8).b. Exogenous Factor I provides relief in acute disease.
2. Factor H deficiency also results in increased complement activation, C3 de-pletion, and an increased risk of infection.
3. C1 inhibitor (C1 Inh) deficiency (hereditary angioedema) and C4b-BPdeficiency are characterized by episodic cutaneous and submucosal edema.a. Both conditions result in unabated activation of the classical complement
pathway. b. A C2-derived peptide is thought to cause increased vascular permeability
and localized edema in hereditary angioedema.c. C1 Inh also regulates the production of bradykinin, which can have a simi-
lar effect on endothelial permeability.4. Paroxysmal nocturnal hemoglobinuria (PNH) is due to a failure of cells to
express glycosylphosphatidylinositol (GPI)-linked membrane proteins, includ-ing CD59 and CD55 (decay accelerating factor).a. CD59 blocks insertion of C8 and C9 into the membrane.b. CD55 inhibits C3 and C5 convertases on the cell surface.c. Erythrocytes of PNH patients are highly susceptible to complement-
mediated lysis.
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Table 15–6. Primary deficiencies in the complement system.
Type of Deficiency Components Involved Clinical Characteristics
Classical pathway C1q,r,s, C4, C2 Lupus nephritisBacterial, viral, and fungal
infections
Alternative pathway P, B, D Neisseria infectionsPyogenic infections
Lectin pathway MBL Diverse infections
Common components C3 Pyogenic infections
Terminal components C5–C8 Disseminated Neisseria infections
Inhibitors C1 Inh, H, I, C4b-BP Angioedema, nephritis, infections
Cell surface inhibitors DAF, CD59 Paroxysmal nocturnal hemoglobinuria
Receptors CR3, CR4 Leukocyte adhesion, pyogenic infections, delayed wound healing
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D. Complement deficiencies and autoimmunity are often associated with one an-other.1. Patients with defects in the early classical pathway components often develop
a lupus-like nephritis.2. Circulating immune complexes in autoimmunity deplete the early classical
components. 3. Autoantibodies to complement components (eg, anti-C1q) are sometimes
produced by patients with systemic lupus erythematosus (SLE) (Chapter 16).4. Patients with SLE, Sjögren’s syndrome, and autoimmune hemolytic anemias
often show decreased expression of complement receptor 1 (CR1) on theirerythrocytes.
E. The treatment of complement deficiencies focuses primarily on controlling infec-tions and correcting acute symptoms.1. Aggressive antibiotic therapy is the first objective for infections.2. Plasma infusion or injection of individual components (eg, recombinant C1
Inh) has some clinical value for acute disease.3. The various treatments for autoimmunity associated with complement defi-
ciencies are discussed in Chapter 17.
VI. Inherited innate immune defects can cause inflammatory or infectiousdiseases.A. An increased susceptibility to infections results from mutations in interleukin-1
receptor-associated kinase (IRAK) of the Toll-like receptors.B. Mutations in mannose-binding lectin increase the risk of infection, especially in
the presence of other chronic diseases (eg, cystic fibrosis). C. Deficiencies in the antimicrobial Nod proteins (Chapter 1) are thought to con-
tribute to the induction of inflammatory bowel disease.
VII. Acquired or secondary immune deficiency states typically show adultonset. A. Acquired immune deficiencies can also result from infections.
1. Acquired immune deficiency syndrome (AIDS) is the most prevalent im-mune deficiency in the United States.a. CD4+ T cells are depleted by the lymphotrophic virus human immunode-
ficiency virus-1 (HIV-1).b. Th1 cell functions are particularly affected. c. Opportunistic infections with intracellular pathogens (Table 15–7) are the
primary causes of morbidity and mortality. 2. Transient neutropenia in children is seen in some viral (eg, measles) and bac-
terial (eg, tuberculosis) infections. 3. A number of microbial pathogens (eg, herpesviruses) have developed immune
evasion mechanisms that cause selective immunosuppression of the host(Chapter 14).
B. Immune deficiency can arise secondary to therapy.1. Splenectomy impairs the ability to produce antibodies.
a. Splenectomized patients are at increased risk for sepsis.b. Splenectomy decreases IgG antibody responses to polysaccharide vaccines.
2. Immunosuppressive drugs increase the risk of infections.
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a. Many chemotherapeutic agents used to treat malignancies are immuno-suppressive.
b. Drugs that block allograft rejection (Chapter 17) also inhibit immune re-sponses to microbial pathogens.
c. Corticosteroids increase the risk of infection when used at high doses orover long periods of time.
d. Disease-modifying antirheumatic drugs (DMARDS) used for treatingchronic autoimmune diseases carry a similar risk of increasing infection rates.
e. The use of certain anticytokine reagents can inhibit protective immunityto specific pathogens [eg, antitumor necrosis factor (TNF)-α antibodiesand tuberculosis].
C. Cancer is a common cause of secondary immune deficiencies.1. Malignancies that grow within the bone suppress hematopoiesis, including
lymphopoiesis and granulopoiesis. 2. Lymphoid malignancies (eg, lymphomas) inhibit normal lymphocyte func-
tions in the peripheral lymphoid tissues.3. Cancer cells often produce excessive quantities of cytokines and growth factors
that cause immune imbalance.D. Protein-losing enteropathies, extensive burns, and nephrotic syndrome result
in protein loss, hypogammaglobulinemia, and hypocomplementemia. E. Common variable immune deficiency is a heterogeneous syndrome that shows
early or adult onset. 1. B cell numbers are normal, but plasma cells are infrequent and antibody pro-
duction is impaired.2. T cell numbers and subsets are also typically normal, but cellular immunity
can be decreased.3. Bacterial agents constitute the greatest threats of infection, which resemble
those seen in XLA.
CLINICAL PROBLEMSA 4-year-old child is referred with the diagnosis of type 1 LAD. She has a history of recur-rent bacterial infections, including pneumonias and skin abscesses. Radiography demon-strates granuloma-like lesions in her lungs and liver. However, the data in the followingtable suggest this condition has not been properly diagnosed.
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Table 15–7. Opportunistic pathogens causing infections in AIDS.
Bacteria Fungi Viruses Parasites
Mycobacteria Pneumocystis Herpes simplex Toxoplasma Salmonella Cryptococcus Cytomegalovirus Cryptosporidium
Candida Varicella-Zoster Leishmania
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1. Which of the elements in the table is inconsistent with a diagnosis of type 1 LAD?
CD Marker Patient (%) Normal Range (%)
CD2 76 75–92
CD3 75 60–85
CD4 52 30–65
CD8 26 20–52
CD11a 65 65–85
CD18 73 70–86
CD19 12 7–17
CD45 52 44–62
A. The CD2 value
B. The CD19 value
C. The CD11a value
D. The CD45 value
E. The CD3 value
A 3-month-old child presents with a history of persistent diarrhea and oral thrush begin-ning at age 3 weeks and has developed signs and symptoms consistent with Pneumocystiscarinii pneumonia. Both he and his parents are HIV negative based on serological andpolymerase chain reaction (PCR) testing. Complete blood counts demonstrate profoundlymphopenia.
2. Which of the following blood cell types should show normal numbers if this conditionwas caused by a Rag deficiency?
A. CD3+ cells with a CD4 coreceptor
B. CD19+ cells
C. Single-positive thymocytes
D. Memory B cells
E. NK cells
An 8-month-old male child has an apparent antibody deficiency. The diagnosis has beennarrowed to two possibilities.
3. Measuring which of the following immune parameters would distinguish hyper-IgMsyndrome (type 1) from X-linked agammaglobulinemia?
A. IgG levels in the serum
B. CD19+ cells in the blood
C. IL-2 production by the patient’s lymphocytes in vitro
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D. NK cell-mediated cytotoxicity in vitro
E. IgA levels in the saliva
A pediatric patient has a history of recurrent infections, and it is hypothesized that she hasa defect in the neutrophil-mediated killing of phagocytized bacteria.
4. Which of the following laboratory assays would most directly test this hypothesis?
A. Complement fixation test
B. Quantitative test for serum Igs
C. NBT dye reduction test
D. Flow cytometry for CD18 expression
E. Complete blood count and differential
An adolescent with a history of childhood upper respiratory tract infections and diarrheacontinues to have recurring sinusitis, which is attributed to Pseudomonas aeruginosa, agram-negative bacterium. Laboratory tests over the past 5 years have repeatedly indicatedthat he has normal T cell numbers (based on CD3, CD4, and CD8), normal serum com-plement levels and activity, and normal serum IgM and IgG levels for his age. Isohemag-glutinin titers are normal. Neutrophil numbers and function (chemotaxis,opsonophagocytosis, and respiratory burst) are all normal. His IgG antibody response totetanus toxoid challenge is also within the normal range. He shows 4+ reactions in delayedhypersensitivity skin tests against several common fungal antigens.
5. What therapy is appropriate for this patient?
A. Antibiotics only
B. Antibiotics and IVIG
C. Antibiotics, IVIG, and stem cell transplantation
D. Stem cell transplantation
E. Antibiotics and IFN-γJohnny is an 8-month-old child with recurrent fungal and viral infections. His blood lym-phocyte numbers are normal and they bind IL-2 in vitro. It has been determined that hisparents are both heterozygous for a mutation in their ZAP-70 genes that can explainJohnny’s disease.
6. In addition to antimicrobial agents to treat his infections, what therapy should be con-sidered for Johnny?
A. Thymus transplant
B. IVIG and all of the pediatric vaccines
C. Recombinant IL-2
D. Stem cell transplantation
E. Besides antimicrobial agents, there is no effective therapy for this patient.
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ANSWERS
1. The correct answer is C. The diagnosis of LAD type 1 requires demonstrating that thepatient lacks CD18 or any of the α chains that pair with the CD18 β chain (ie,CD11a, CD11b, or CD11c). This patient has normal levels of CD11a, which meansshe does not have LAD type 1.
2. The correct answer is E. Rag-deficient SCID patients show a T−B−NK+ overall lympho-cyte phenotype.
3. The correct answer is B. In hyper-IgM syndrome, normal numbers of B cells are pre-sent in the periphery. However, they do not receive the normal signaling from Th cellsdue to a defect in the coreceptor ligand CD154. In XLA the absence of the Btk kinaseblocks B cell differentiation at the pre-B cell stage, and the patients have no peripheralCD19+ B cells.
4. The correct answer is C. The NBT dye reduction test measures cellular production ofoxidants, which are important in the oxygen-dependent killing of microbes by neu-trophils (Chapter 1). The other tests could confirm phagocyte dysfunction as well, butwould not directly relate to intracellular killing function.
5. The correct answer is A. This patient lacks any clear evidence of an immune deficiencythat would explain his recurrent bacterial infections. There is no rationale for stem celltransplantation, and there is no antibody defect that would suggest giving IVIG. Onlyconventional antibiotic therapy is indicated for the treatment of the infection.
6. The correct answer is D. ZAP-70 deficiency affects TCR-initiated signaling in his Tcells. Replacing the defective T cells with normal T cell precursors would theoreticallybe of value here.
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I. Tolerance is an acquired condition of specific unresponsiveness to anantigen. A. Autotolerance (unresponsiveness to self antigens) is established within B and T
lymphocytes as they encounter self antigens during development.1. Self tolerance is antigen specific and can be induced either in a primary lym-
phoid organ or in the periphery. 2. Autotolerance continues to be established throughout life, even after the thy-
mus atrophies. B. Three mechanisms contribute to the induction of tolerance.
1. Clonal deletion results in the apoptosis of specific B and T cell clones.a. Clonal deletion generally occurs among immature B and T cells through a
process called negative selection (Chapters 9 and 10).b. Deletion requires antigen recognition by immature lymphocytes through
their B cell receptor (BCR) or T cell receptor (TCR). 2. Clonal anergy is a form of unresponsiveness in lymphocytes caused by antigen
recognition in the absence of essential stimulatory coreceptor signals.a. Antigen presentation by antigen-presenting cells (APCs) that lack the B7
ligand for the CD28 coreceptor induces T cell anergy.b. Antigen presentation by cells that engage the inhibitory cytotoxic T lym-
phocyte-associated protein 4 (CTLA-4) coreceptor can also induce T cellanergy.
3. Tolerance, including autotolerance, can also be mediated by active suppressorcells in the periphery.a. Regulatory T cells (Treg cells) mediate unresponsiveness to specific anti-
gens.b. Treg cells are induced in both the thymus and the periphery by autoanti-
gens.c. Suppression is generally mediated by the production of inhibitory cytokines,
such as interleukin (IL)-10 and transforming growth factor (TGF)-β.C. Autotolerance is established at two levels.
1. Central tolerance to self antigens is established during the differentiation of Band T cells in the bone marrow and thymus, respectively.a. Central tolerance results in the deletion of autoreactive clones (negative se-
lection).
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b. Self-specific B cells can be rescued from clonal deletion by undergoing sec-ondary immunoglobulin (Ig) locus rearrangements (BCR editing.)
2. Peripheral tolerance involves all three mechanisms of tolerance induction—deletion, anergy, and suppression.a. The induction of autotolerance in the periphery continues throughout life.b. Because quiescent autoreactive B and T cell clones reside in normal individ-
uals, autoimmunity is common.
TRANSPLANTATION TOLERANCE
• It is not uncommon for transplant recipients to become tolerant to their foreign organ grafts over time,despite significant genetic disparities with the organ donor.
• Pretransplantation lymphoablation appears to favor the induction of tolerance, as does the establish-ment of donor–recipient chimerism when donor bone marrow cells are provided.
• The continual exposure of the recipient to the HLA antigens of the donor may also induce active sup-pressor cells, including Treg cells.
• Blocking CD28/B7 and CD40/CD154 costimulatory signaling may be another mechanism for inducingspecific unresponsiveness to allografts.
• The ultimate goal of inducing transplantation tolerance is to reduce the dependence on powerful im-munosuppressive therapies in the posttransplant period.
II. Autoimmunity results from the loss of self tolerance. A. The molecular mimicry theory of autoimmunity proposes that autoimmunity
occurs when microbial antigens cross-react with self antigens.1. Antibodies to the M protein of Streptococcus pyogenes that are induced during
infection can react with cardiac autoantigens of the sarcolemma and heartvalves and cause rheumatic fever.
2. Antibodies to Treponema pallidum induced during syphilis can cross-react withhuman fibronectin and collagen.
3. Antibodies to the insulin receptor are induced during papilloma virus infec-tions.
B. The costimulatory theory of autoimmunity proposes that silent autospecificlymphocytes are activated when tissues inappropriately express stimulatory core-ceptor ligands. 1. Major histocompatibility complex (MHC) class II molecules are expressed by
pancreatic β cells in type 1 diabetes mellitus. 2. Microglial cells of patients with multiple sclerosis express B7.
C. Autoimmunity is induced when cryptic or sequestered autoantigens that arenormally not seen by the immune system are released to the periphery.1. Autoimmune uveitis is thought to develop when ocular antigens released from
a damaged eye induce immune damage to the contralateral eye.2. Autoantigens of spermatogonia can be recognized as nonself if they are later re-
leased from the testes by vasectomy. D. Modified self antigens can induce autoimmune responses.
1. Autoimmune hemolytic anemias result when drugs bind to erythrocyte surfaceproteins.
2. Autoantibodies to the Fc domains of IgG molecules (rheumatoid factors) areoften produced in rheumatoid arthritis.
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VASECTOMY AND AUTOIMMUNE ORCHITIS
• Vasectomy is the most common means by which men elect permanent sterilization for the purpose ofcontraception.
• Vasectomy does not halt spermatogenesis, and sperm can become accessible to the immune systemfollowing the procedure.
• Sperm-agglutinating antibodies develop in over 50% of vasectomized males.
• Epididymitis and orchitis mediated by autoantibodies occur at a rate of 5–6%.
III. Autoimmunity often exists without overt autoimmune disease.A. The elderly commonly produce low-affinity autoantibodies that do not cause dis-
ease. B. Witebsky’s postulates establish a set of criteria for designating a disease as au-
toimmune in nature.1. Autoantibodies or autoreactive T cells must be demonstrated in the patient.2. The autoantigen(s) must be identified.3. Immunizing a laboratory animal with the autoantigen must induce a compara-
ble autoimmune response and autoimmune disease.4. The disease manifestations must be transferable to a naive recipient with au-
toantibody or autospecific T cells.C. Several human diseases appear to satisfy Witebsky’s postulates.
1. Myelin-specific T cells of the type found in multiple sclerosis can transfer dis-ease to laboratory rats and mice.
2. The lesions found in myasthenia gravis can be duplicated in animals by thetransfer of patient serum.
3. Harrington’s experiments with idiopathic thrombocytopenia purpura clearlyidentify this condition as an autoimmune disease.
WILLIAM HARRINGTON AND IDIOPATHIC THROMBOCYTOPENIA PURPURA
• In 1951, a young hematologist named William Harrington was caring for a group of patients withbleeding disorders and low platelet counts.
• Dr. Harrington proposed that their thrombocytopenia was immune based.
• After injecting himself with the plasma of one of his patients, he developed severe, but transient throm-bocytopenia.
• Because his megakaryocytes were spared destruction, he eventually recovered.
• This experiment firmly established that autoantibodies can cause human disease.
D. The diagnosis of autoimmune diseases is aided by laboratory tests.1. Some tests detect tissue-bound autoantibodies.
a. Antibodies to glomerular basement membrane antigens in Goodpasture’sdisease show a characteristic linear distribution in the kidney by immuno-fluorescence.
b. By contrast, the “lumpy-bumpy” appearance of IgG in the glomerulus istypical of immune complex autoimmune diseases (eg, systemic lupus ery-thematosus or SLE).
2. Many laboratory tests are designed to detect circulating autoantibodies.a. Antinuclear antibodies (ANA) are detected by immunofluorescence.
CLINICALCORRELATION
CLINICALCORRELATION
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(1) The autoantigens include DNA, histones, and nucleolar proteins.(2) These antibodies are seen in SLE, Sjögren’s syndrome, and scleroderma.
b. Antineutrophil cytoplasmic antigen (ANCA) is characteristic of certainforms of autoimmune nephritis and vasculitis (eg, Wegener’s granulomato-sis).
c. Rheumatoid factor (RF) is common to rheumatoid arthritis and a numberof other autoimmune diseases.(1) RF is an autoantibody to the Fc region of IgG.(2) RF is mostly IgM anti-IgG, but IgG and IgA autoantibodies have also
been described.d. The Coombs test detects IgG antibodies on erythrocytes and platelets.
(1) These antibodies can be specific for endogenous or exogenous (ie, hap-tenic) cell surface antigens.
(2) “Coombs-positive” is synonymous with immune-based when used to de-scribe an anemia.
3. Tests that measure the serum concentrations of complement can be used tofollow the status of autoimmune diseases.a. Complement activity is often depressed during acute exacerbations of im-
mune complex autoimmune diseases.b. Measuring complement levels can be useful for monitoring the success of
therapy.
IV. The spectrum of autoimmune diseases ranges from those that are organspecific to those that are essentially systemic in nature.A. In organ-specific autoimmune diseases symptoms reflect the distribution of the
target autoantigen(s).1. Hashimoto’s thyroiditis, pernicious anemia, and Addison’s disease are examples
of organ-specific autoimmune diseases.2. The organ-specific disease manifestations of these conditions (eg, thyroid dys-
function) are important clues to their diagnosis.B. Systemic autoimmune diseases (ie, the rheumatological disorders) typically in-
volve the skin, kidneys, muscles, joints, and blood vessels.1. Tissue damage is widely distributed. 2. Symptoms can reflect the deposition of soluble immune complexes, which is an
important step in disease pathogenesis.
AUTOIMMUNE POLYENDOCRINE SYNDROME
• Autoimmune polyendocrine syndrome (APS) type 1 is a rare condition caused by a mutation in thegene for the transcription factor autoimmune regulator (AIRE).
• Patients present with chronic mucocutaneous candidiasis, hypoparathyroidism, and/or adrenal insuf-ficiency.
• AIRE is expressed in thymic epithelial cells and may control induction of self tolerance.
• Twenty percent of affected individuals develop type 1 diabetes mellitus.
C. Tissue damage and symptoms in autoimmune diseases can change with time, be-cause autoantibody responses become increasingly polyspecific. 1. The initial autoantibody is specific for a dominant self epitope.2. Autoimmunity broadens with time by epitope spreading (Figure 16–1).
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a. B cells specific for the initial epitope elicit new responses by presenting addi-tional epitopes on the same antigen (intramolecular spreading).
b. B cells specific for the epitopes of the first autoantigen can cross-react with asecond autoantigen (intermolecular spreading).
V. One of four pathogenic mechanisms underlies the development of mostautoimmune diseases (Table 16–1).A. Antireceptor autoantibodies can cause autoimmune disease.
1. Myasthenia gravis is a neurological condition presenting as muscle weaknessand fatigue.a. Manifestations include diplopia, dysphonia, and difficulty swallowing,
breathing, and walking. b. Antagonistic antibodies to the acetylcholine receptor block neurotransmis-
sion at motor end plates.2. Grave’s disease is mediated by agonistic antibodies to the thyroid-stimulating
hormone (TSH) receptor.a. Anti-TSH receptor antibodies are diagnostic.b. Hyperthyroidism and thyroid hyperplasia are common. c. Females are affected seven times more often than males.d. Many patients require thyroid ablation by radiotherapy or surgery.
B. Cytotoxic immune tissue injury is the basis for many forms of organ-specific au-toimmune disease.1. Coombs-positive hemolytic anemias and thrombocytopenias result from the
immune lysis and/or clearance of blood cells.a. Complement plays a central role in cell destruction.b. “Cold reactive antibodies” are IgM and show high avidity.
(1) They are more commonly found after certain infections (eg, my-coplasma).
(2) They typically induce intravascular hemolysis. c. “Warm reactive antibodies” are IgG and have a lower avidity.
1
Immunodominantepitope
Intramolecularspreading
Intermolecularspreading
2 3 4
a 3 b C
Figure 16–1. Epitope spreading in autoimmunity.
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(1) These antibodies cause Fc receptor-mediated clearance of erythrocytes.(2) They are often induced by drugs that bind to cell surface proteins.
2. The direct Coombs test detects IgG antibodies on a patient’s erythrocytes.3. The indirect Coombs test detects circulating IgG autoantibodies that can
react with endogenous erythrocyte antigens (eg, Rh).
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Table 16–1. Major pathogenic mechanisms underlying autoimmune diseases.
Initial Target Distinguishing Clinical Mechanism of Disease Examples Autoantigen Features
Antireceptor Myasthenia gravis Acetylcholine Muscle fatiguabilityautoantibody receptor
Grave’s disease Thyroid-stimulating Hyperthyroidism; goiterhormone receptor
Pernicious anemia Intrinsic factor Vitamin B12 deficiencyAddison’s disease Adrenal cell antigens Adrenal insufficiency
Cytotoxic immune injury Coombs-positive Endogenous erythro- Intravascular hemolysis, hemolytic anemia cyte antigens or clearance, and anemia
haptensCrohn’s disease Unknown Transmural colitis and
ileitis, ulcerationGoodpasture’s disease Basement Nephritis, pneumonitis
membrane collagenPemphigus vulgaris Desmosome antigens Blistering skin lesions,
in the skin immunoglobulin G staining on epidermal cells
Rheumatic fever Cardiac muscle Heart valve damageantigens
Sjögren’s syndrome Nucleoproteins Dry eyes and mouthRo and La
Thrombocytopenia Platelet integrins Hemorrhagic purpurapurpura
Immune complex tissue Drug-induced Drug hapten Vasculitis, hemorrhage, injury serum sickness arthralgia, nephritis
Rheumatoid arthritis Unknown Synovitis, arthritis, carti-lage and bone loss
Systemic lupus Nucleic acids, Malar skin rash, arthral-erythematosus nucleoproteins gia, anemia, arthritis,
nephritis
Cellular immune Diabetes mellitus β cell antigens Hyperglycemia; pancre-tissue injury (type 1) atic β cell loss
Hashimoto’s Thyroglobulin; Hypothyroidismthyroiditis thyroid peroxidase
Multiple sclerosis Myelin proteins Progressing sensory deficits, fatigue, weakness
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4. Drug-induced autoimmune hemolytic anemias are caused by several mecha-nisms. a. Penicillin induces direct Coombs-positive anemias.
(1) The drug binds directly to the erythrocyte surface and induces an an-tidrug antibody.
(2) These conditions improve when the drug is discontinued.b. Methyldopa induces anemias that are direct and indirect Coombs
positive. (1) This drug induces an antidrug antibody that cross-reacts with an Rh
antigen.(2) Treatment may require immunosuppression and/or plasmapheresis to
remove the autoantibodies.c. Other drugs can induce autoantibodies that form immune complexes with
the drug.(1) The immune complexes can bind to the erythrocyte surface through
CR1 (Chapter 8).(2) Such conditions are direct and indirect Coombs positive.(3) Treatment may require immunosuppression and/or plasmapheresis to
remove the immune complexes.5. Goodpasture’s disease is mediated by IgG antibodies to basement membrane
antigens, which together with neutrophils cause nephritis and pneumonitis.a. Autoantibodies in this disease are directed at epitopes of type IV collagen
that are found in basement membranes.b. Treatment involves antiinflammatory and immunosuppressive drugs and
plasmapheresis. c. End-stage renal disease may require kidney transplantation.
INFECTIONS AND AUTOIMMUNITY
• An increased incidence of infection is not always seen in autoimmune diseases.
• However, when autoimmunity adversely affects the integrity of an epithelial barrier (eg, Crohn’s dis-ease or Sjögren’s syndrome) opportunistic infections can occur.
• Complement consumption in immune complex autoimmune diseases can also impair host responsesto infectious agents.
• Immunosuppressive therapies for autoimmunity increase the risks of infection.
• Paradoxically, with a decrease in the overall infection rate in developed countries, an increase in the in-cidence of allergy and autoimmune disease has occurred.
• This may reflect the failure of a microbe-poor environment to induce adequate inhibitory immune re-sponses (eg, Treg cells) that prevent allergy and autoimmunity.
C. Immune complex-mediated diseases share certain clinical features.1. Drug-induced serum sickness results when antibodies to drugs (eg, penicillin)
form soluble immune complexes with their antigens.a. These complexes deposit in the skin, blood vessel walls, joints, and kidneys,
activate complement, and recruit inflammatory cells.b. Vasculitis, hemorrhage, arthralgia, skin rashes, and nephritis are among the
principal clinical findings.2. SLE is one of the most common autoimmune disease in women 20–40 years of
age, especially African-Americans (Table 16–2).
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CLINICALCORRELATION
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a. The condition is characterized by fever, arthralgia, nonerosive arthritis,myalgia, photosensitivity, skin rashes, anemia, and glomerulonephritis.
b. The autoantibodies produced in patients with SLE become increasinglypolyspecific with epitope spreading.(1) Antibodies to double-stranded DNA are diagnostic.(2) Additional autoantibodies are produced against nuclear antigens (his-
tones, ribonuclear proteins) and erythrocyte surface antigens.c. Immunofluorescence staining for immune complexes or C3b in the kidney
shows a “lumpy-bumpy” pattern.d. Therapy for this condition is directed at reducing pain, inflammation, and
autoantibody production (Table 16–3).3. Rheumatoid arthritis is the most common autoimmune disease in the United
States today.a. Patients usually first present with morning stiffness and joint pain.b. Synovitis results from the infiltration of lymphocytes and macrophages and
synovial growth in the form of a pannus.c. Th1 cells infiltrate the joint and contribute to macrophage and osteoclast
activation.
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Table 16–2. Epidemiology of autoimmune diseases.
Approximate Incidence Disease HLA Associations Female to Male Ratios (per 100,000)
Myasthenia gravis A1, B8, DR4 3
Grave’s disease 7 100–300
Addison’s disease DR3, DR4 4
Sjögren’s syndrome B8, DRw52, DR3 9 <600
Crohn’s disease DR1 with DQw5 200
Pemphigus DR4, DRw6 3
SLEa DR2, DR3 5 50
Diabetes mellitus (type 1) DR4 or DR1 with DQ1 <1 250
Rheumatoid arthritis DR4, DR1 3 1000–3000
Hashimoto’s thyroiditis DR3, DR4, DR5 10 500
aSLE, systemic lupus erythematosus.
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d. Macrophages activate matrix metalloproteases and osteoclasts, which leadsto cartilage and bone erosion.
e. Immune complexes, including rheumatoid factor, are present in the jointspaces.
f. Therapy includes immunosuppression, synovectomy, and joint replacement(Table 16–3).
D. Cell-mediated autoimmune diseases do not require autoantibodies. 1. Multiple sclerosis is a neurodegenerative condition resulting from central ner-
vous system (CNS) demyelination by activated macrophages.a. Inflammation is initiated by CD4+ T cells specific for myelin autoantigens
(myelin basic protein, myelin oligodendrocyte glycoprotein).b. Th1 cytokines recruit and activate T cells and macrophages. c. MHC class II and the B7 coreceptor ligand are induced on astrocytes and
microglia.2. Type 1 (immune-mediated) diabetes mellitus involves the destruction of
pancreatic islet β cells and hyperglycemia.a. Target autoantigens include the insulin receptor, β cell granule proteins,
and insulin.b. Increased HLA-DR expression on β cells is common.
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Table 16–3. Therapies used to treat autoimmune diseases.a
Treatment Intent Diseases
Plasmapheresis Reduce circulating Grave’s disease, hemolytic autoantibodies and immune anemias, SLEcomplexes
NSAIDs Reduce pain and inflammation Rheumatic diseases in general
Corticosteroids Antiinflammatory effects RA, SLE
Cytotoxic drugs (azathioprine) Inhibit lymphocyte activation SLEand proliferation
Anticytokine reagents Block proinflammatory Crohn’s disease (TNF-α), RA, cytokine effects (IL-1β or TNF-α)
Corrective surgery Removal or replacement Crohn’s disease, Hashimoto’s of damaged tissues thyroiditis, RA
Transfusion and transplantation Organ or tissue replacement Hemolytic anemias, type 1 diabetes mellitus
aSLE, systemic lupus erythematosus; NSAIDs, nonsteroidal antiinflammatory drugs; RA, rheumatoid arthritis; TNF,tumor necrosis factor; IL, interleukin.
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c. CD4+ Th1 cells, CD8+ T cells, and macrophages infiltrate the islets and in-duce β cell apoptosis.
d. Insulin replacement by injection, pancreas transplantation, or islet cell trans-plantation is the preferred therapy.
3. Sjögren’s syndrome is a disease involving T cell-mediated damage to lacrimaland salivary glands that leads to dry eyes and dry mouth (sicca symptoms).
CLINICAL PROBLEMSA patient recently diagnosed with SLE is experiencing significant symptoms of 3 weeksduration that include edema and skin rash. Her serum blood urea nitrogen (BUN) andcreatinine levels are increased, and a biopsy of her kidney shows IgG and C3b at theglomerular basement membrane. Her serum complement levels are monitored over time.
1. Which of the following findings would be most consistent with a worsening clinicalcourse?
A. A decline in C9 levels
B. A decline in C3 and C4 levels
C. An increase in Factor P levels
D. An increase in C1 inhibitor (C1 Inh) levels
E. A decline in C7 levels
2. Of the following laboratory test findings, which would have been most useful in mak-ing the initial diagnosis of this disease?
A. A positive ANA
B. A positive cross-match
C. Bence–Jones urinary proteins
D. A positive mixed lymphocyte reaction
E. Antibodies to myelin basic protein
Helen’s physician has prescribed methyldopa for the treatment of her hypertension. Shevisits the outpatient medicine clinic several months later complaining of fatigue and has anoticeable pale color in the palms of her hands. Her hemoglobin is 9.5 g/dL (normal range= 13–15 g/dL).
3. What laboratory test should be ordered to determine if her anemia is due to an anti-body?
A. HLA typing
B. Antithyroglobulin
C. Coombs test
D. ANA
E. Major cross-match
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Bill is a 30-year-old man who presents with lower right quadrant abdominal pain, a 10-pound weight loss over the past month, fever, and nonbloody diarrhea. Barium enemacontrast imaging indicates mucosal swelling of the wall of the ileum and ascending colon.A biopsy of the colon shows the presence of transmural granulomatous inflammation.Laboratory tests indicate mild anemia, leukocytosis, and decreased total serum protein andalbumin, which suggest anorexia.
4. Which of the following therapies would be expected to be most beneficial in treatingthis condition?
A. Plasmapheresis
B. Anti-tumor necrosis factor (TNF)-αC. Recombinant C1 Inh
D. Appendectomy
E. Antifungal agents
A 72-year-old man complains of bilateral swelling and pain in the joints of his hands andfeet. Several of his proximal phalangeal joints are noticeably deformed. A radiograph of theright hand shows a narrowing of the joint spaces in three digits.
5. Which of the following additional findings would support a diagnosis of rheumatoidarthritis?
A. A decreased erythrocyte sedimentation rate
B. Serum antibodies to double-stranded DNA
C. Antibodies to IgG in the serum
D. A positive response to antibiotics
E. Autoantibody to the TSH receptor
ANSWERS
1. The correct answer is B. Acute episodes in lupus are accompanied by complement de-pletion by activation of the classical pathway. This leads to a decline in the serum levelsof C1, C2, C3, and C4.
2. The correct answer is A. Over 95% of lupus patients have antinuclear antibodies. Theother choices do not fit a diagnostic approach to autoimmunity, except choice E. Anti-bodies to myelin are typical of multiple sclerosis, but not SLE.
3. The correct answer is C. The most appropriate test for establishing an immune basisfor an anemia is the Coombs test, which detects IgG antibodies on erythrocytes. Thispatient’s fatigue is most likely related to her low erythrocyte mass.
4. The correct answer is B. This case fits the classic signs and symptoms of Crohn’s dis-ease and the imaging and laboratory data support this diagnosis. Chronic inflammationis maintained by the activation of a Th1 type of cytokine production, including IL-12,
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interferon (IFN)-γ, and TNF-α. Anti-TNF-α has proven effective in treating Crohn’sdisease in many patients.
5. The correct answer is C. Although not diagnostic of this condition, the presence ofrheumatoid factor certainly distinguishes rheumatoid arthritis from several other formsof arthritis. Lupus patients can develop arthritis, but the condition of not erosive in na-ture. Increased sedimentation rates are common in acute disease.
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I. The principles of transplantation predict the survival of transplantedtissues. A. Tissue or organs transplanted within an individual are accepted.
1. Such grafts are called autografts.2. Examples of autografts include skin transplants to treat local burns and cos-
metic hair follicle transplantation to treat hair loss.B. Grafts exchanged between genetically identical individuals are accepted.
1. These grafts are called isografts.2. The donor and recipient are isogeneic or syngeneic to one another.
C. Grafts between genetically dissimilar individuals are rejected.1. The donor and recipient are allogeneic to one another.2. The grafts are referred to as allografts.
D. Grafts exchanged between species are normally rejected.1. The donor and recipient are xenogeneic. 2. The grafts are called xenografts.
E. Foreign histocompatibility antigens initiate graft rejection.1. Major histocompatibility complex (MHC) alloantigens (ie, human HLA)
are the strongest stimuli for inducing allograft rejection.2. Minor histocompatibility antigens and tissue-specific antigens can mediate
graft rejection. a. Vascular endothelial cells express ABO antigens that can stimulate hypera-
cute rejection.b. Endothelium-specific antigens can trigger graft rejection.
3. MHC alloantigens are recognized directly by large numbers of cross-reactingCD4+ and CD8+ T cells (Figure 17–1).a. Most T cell receptors (TCRs) cross-react with allogeneic forms of MHC. b. Up to 15% of all peripheral T cells can be activated by a single MHC al-
loantigen.4. Multiple MHC incompatibilities lead to more vigorous graft rejection than
does a disparity at a single locus (Figure 17–2).5. Disparities at MHC class I + MHC class II loci induce greater responses than
does either a class I or a class II difference alone.6. Prior immunization can increase the pace of allograft rejection.
N
C H A P T E R 1 7C H A P T E R 1 7
TRANSPLANTATION
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a. “First set” rejection occurs within days because the number of T cells acti-vated by a foreign graft is large.
b. Repeated exposure to the same MHC alloantigens (eg, through bloodtransfusions) can cause even more rapid rejection (“second set” rejection).
F. The fate of allografts varies somewhat depending on the nature of the tissue ororgan transplanted (Table 17–1).
Chapter 17: Transplantation 205
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HLA-A1CTL
TCRViral peptide
Cross-reacts
Peptide fromallogenic cell
HLA-A1Virus-infected self cell
HLA-A1CTL
HLA-A2Allogenic cell
Class I MHC
Figure 17–1. Recognition of an allogeneic major histocompatibility complex (MHC)molecule by T cells. CTL, cytotoxic T lymphocyte; TCR, T cell receptor.
0
5
10
15
20
25
30
35
45
45
Gra
ft f
ailu
re r
ate
(%)
0 1 2 3 4 5 6
Number of HLA mismatches
Living relatedallografts
Cadavericallografts
Figure 17–2. Influence of HLA on 5-year allograft failure rates.
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CORNEAL TRANSPLANTS
• Approximately 40,000 corneal transplants are performed in the United States each year.
• The donors are not routinely matched with recipients for HLA, and recipients do not receive systemicimmunosuppression following transplantation.
• The immunologically privileged status of the anterior chamber of the eye results in a low level of graftrejection (~10%).
• Immune privilege is maintained by a lack of lymphatic drainage and the expression of Fas ligand(Chapter 6) on corneal endothelial and epithelial cells.
• Invading activated T cells expressing Fas are killed by binding to ocular Fas ligand.
• When they occur, rejection episodes can be treated with topical corticosteroids.
II. Allograft rejection involves a diverse set of immune mediators (Figure17–3). A. CD4+ Th1 cells activate various effector cells by secreting cytokines.
CLINICALCORRELATION
Table 17–1. Special considerations related to particular forms of transplantation.
Organ or Tissue Transplanted Considerations
Kidney 95% overall success rate after 1 year when living related kid-neys are used; diabetes is the most frequent cause of end-stage renal failure
Heart Reserved for imminently life-threatening cardiac disease; oftencombined with lung transplantation; relaxed criteria for donorselection due to organ shortage and effectiveness of cy-closporin
Lung Low success rate compared to other solid organs
Blood Transfusions are typically tolerated despite HLA disparity; pre-formed anti-HLA antibodies can cause transfusion reactions
Liver Less requirement for HLA typing; evidence that tolerance toallogeneic transplants develops with time; contraindicated incertain malignancies, viral hepatitis, and human immunodefi-ciency virus (HIV) infection
Pancreas Prevention of secondary effects of diabetes; whole organ, seg-mental, or isolated islet cell transplantation possible
Hematopoietic Concern for graft-versus-host disease and infections; graft-stem cells versus-tumor effect beneficial
Cornea Benefits from the privileged status of the anterior chamber
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1. Th1 cells recognize allogeneic HLA-DP, DQ, and DR molecules. 2. The Th1 cell subset produces interleukin (IL)-2, interferon (IFN)-γ, and
tumor necrosis factor (TNF)-α, which activate cytotoxic T cells, natural killer(NK) cells, and macrophages.
B. CD4+ Th2 cells are activated by allogeneic MHC class II molecules.1. The Th2 cytokines IL-4 and IL-5 induce growth, class switching, and anti-
body production by B cells.
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AllogeneicMHC class II
Allograft cell
TH cell
CD8+
CTL
IL-2, IL-12
TNF-βIFN-γ
IL-2
B cellCD8+ TcTH1 cell CD4+ Tc
CD4+
CTL
IL-2 IL-2, IL-4, IL-5, IL-6 IL-2, IFN-γ
Activatedmacrophage
Plasmacell
NK cell ormacrophage
MHCexpression
Lyticenzymesoxidants
Cytotoxicity
Membranedamage
Class I MHCalloantigen
Class II MHCalloantigen
Graft
LysisADCC
C
Fc receptor
Anti-MHCantibody
Figure 17–3. Mediators of allograft rejection. MHC, major histocompatibility complex; TH, T helper;IL, interleukin; TC, cytotoxic T cell; IFN, interferon; TNF, tumor necrosis factor; NK, natural killer;ADCC, antibody-dependent cell-mediated cytotoxicity.
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2. Antibodies specific for allogeneic donor MHC molecules can mediate hyper-acute rejection (see below).
3. Immunoglobulin (Ig) G alloantibodies can promote antibody-dependentcellular cytotoxicity (ADCC) by NK cells and macrophages.
C. Cytokines that mediate allograft rejection are also produced by NK cells (IFN-γ), CD8+ T cells (IFN-γ), and macrophages (TNF-α).
D. CD8+ cytotoxic T cells recognize allogeneic MHC class I molecules.1. Killing is mediated by the perforin–granzyme, Fas–Fas ligand, and TNF re-
ceptor pathways (Chapter 10).2. Rejection is due to apoptotic cell death in the transplanted tissues.
E. Macrophages kill donor cells with oxidants, hydrolytic enzymes, and TNF-α. F. NK cells kill by recognizing the absence of self MHC class I molecules.
III. Three mechanisms of allograft rejection exist. A. Hyperacute allograft rejection occurs within minutes to hours and is mediated
by preformed antibodies in the recipient.1. The principal target antigens include allogeneic HLA and ABO, both of
which are expressed on the donor’s vascular endothelial cells.2. Anti-HLA antibodies are produced in response to pregnancy, blood transfu-
sions, or prior transplants.3. These IgM and IgG antibodies activate complement through the classical
pathway.a. C5a attracts neutrophils to the allograft.b. iC3b promotes neutrophil attachment and activation.c. C3a, C4a, and C5a activate mast cells, which increases the inflammatory
response within the graft.4. Activated neutrophils, monocytes, and NK cells damage the endothelium. 5. Activation and damage to the vascular endothelium cause important hemody-
namic changes in the allograft. a. Tissue factor is expressed by endothelial cells and initiates thrombosis.b. Endothelial cell damage promotes platelet activation, thrombosis, infarc-
tion, edema, and hemorrhage. B. Acute allograft rejection occurs over weeks to months and is mediated by CD4+
Th1 cells, CD8+ cytotoxic T cells, NK cells, and macrophages that infiltrate thegraft.
C. Chronic allograft rejection occurs over months to years. 1. Fibrosis, infarction, and ischemia are common features.2. Chronic rejection is difficult to control by immunosuppression.
IV. Graft rejection can be predicted or prevented by matching the donorand recipient histocompatibility antigens (Table 17–2).A. Tissue typing determines the tissue antigens expressed by prospective donors
and recipients and any preformed immunity to those antigens.1. ABO matching is essential for preventing endothelial damage by isohemag-
glutinins.2. Preformed antibodies to ABO are detected with the major cross-match (incu-
bating donor cells in recipient serum).
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TRANSPLANTATION ACROSS ABO INCOMPATIBILITIES
• Conventional wisdom advises against transplanting organs when an ABO incompatibility exists be-tween the donor and recipient.
• This restriction has limited the number of cardiac transplants, especially those involving infants withcongenital heart defects.
• Recently, it was discovered that ABO incompatibility need not prevent the transplantation of HLA-matched hearts into very young children.
• The isohemagglutinins that mediate hyperacute rejection develop slowly over time in the neonate.
• The antigenic stimulus for inducing isohemagglutinins appears to be the cross-reacting polysaccha-rides of microbial flora.
• The delayed appearance of these natural antibodies reflects a gradual acquisition of commensal or-ganisms during the initial months of postnatal life.
3. HLA typing is performed by molecular techniques [eg, polymerase chain re-action (PCR)].a. The best donor–recipient pair is selected based on similarities between their
HLA genotypes.b. HLA typing and matching can minimize acute rejection. c. Extensive matching of HLA types is not as important in liver transplants as
in kidney transplants (Table 17–1).d. The shortage of heart allografts and the effectiveness of cyclosporine in car-
diac transplantation obviate the need for extensive HLA typing.e. HLA typing is important for identifying haplotype segregation within a
family (Figure 7–7).f. Transplantation using organs from deceased donors may not afford an op-
portunity for detailed tissue typing.g. High-resolution typing of HLA-D region antigens is important in stem cell
transplantation to avoid graft-versus-host disease (GVHD).4. Preformed anti-HLA antibodies are detected with a major cross-match.
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CLINICALCORRELATION
Table 17–2. Prospective HLA typing for the transplantation of solid organ allografts.
Mediator of Rejection
CD8+ Cytotoxic CD4+ Th Cells T Cells Antibodies
HLA antigens recognized HLA-DP, DQ, DR HLA-A, B, C ABO; HLA-A, B,C, DP, DQ, DR
Important typing Type and match Type and match Major cross-matchprocedures HLA-DP, HLA-A, B, C to detect anti-
DQ, DR ABO and Perform mixed anti-HLA
lymphocyte reaction (MLR)
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a. Such antibodies can be formed against either class I or class II alloantigens.b. The major cross-match can prevent hyperacute rejection.
5. The mixed lymphocyte reaction (MLR) detects T cell-mediated reactivitybetween donor and recipient (Figure 17–4). a. The assay measures the recognition of allogeneic MHC by coculturing the
lymphocytes from two individuals. b. The MLR also predicts the potential for GVHD following stem cell trans-
plantation.
TRANSPLANTATION WAITING LISTS
• Recent national data (www.ustransplant.org) indicate that over 80,000 patients in the United Statesare waiting for organ transplants, a number that has doubled in less than 10 years.
• Nearly 60,000 patients await kidney transplantation, while only 15,000 renal transplants are per-formed each year.
• Two-thirds of prospective kidney transplant recipients spend over a year on the waiting list.
• The median time until transplantation is over 3 years.
V. Xenotransplantation has the potential to address the shortage of availabledonor organs and tissues.A. The species providing a xenotransplant to a human patient is determined by
organ physiology as well as social and ethical concerns. 1. Kidneys from minipigs are suitable for transplantation into humans, based on
anatomical and physiological considerations. 2. Pigs are also suitable for genetic manipulation (see the Clinical Correlation on
transgenic pigs in Chapter 8). B. Xenotransplantation carries the risk of transmitting zoonotic infections.
1. Retroviruses similar to human immunodeficiency virus type 1 (HIV-1) are aparticular concern.
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CLINICALCORRELATION
Irradiation
Donor cells
+ HLA-mismatched recipient cells
HLA-matchedrecipient cells
Thymidine uptake = Tcell activation
[3H]thymidine
No Reaction
Figure 17–4. Mixed lymphocyte reaction. *Blood mononuclear cells.
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2. Immunosuppressed transplant recipients are at increased risk for such infec-tions.
C. The primary immunological barrier to xenotransplantation appears to be hyper-acute rejection.1. Natural IgM antibodies against widely distributed ABO-like carbohydrate
xenoantigens are present in nearly all species.2. These antibodies activate complement and initiate neutrophil-mediated dam-
age to vascular endothelial cells.3. Because the membrane complement regulatory proteins [eg, decay-accelerat-
ing factor (DAF)] of the pig do not inhibit the human C3 convertases, uncon-trolled complement-mediated damage also occurs.
D. T cells that recognize the MHC molecules of the xenogeneic species are also acti-vated and mediate strong rejection responses.
VI. Hematopoietic stem cell (HSC) transplantation provides a therapy forhematopoietic disorders, immune deficiencies, and cancer (Table 17–3).A. HSCs bear the CD34 marker and can be purified from bone marrow cells.
1. HSCs can also be purified from peripheral blood after mobilization in thedonor by injection of colony-stimulating factor-granulocyte (CSF-G).
2. For the treatment of malignant conditions, autologous HSCs can be collectedduring remission and transplanted at a later time.
B. Several potential outcomes of stem cell transplantation must be balanced. 1. Rejection of an HSC transplant can be minimized by tissue typing. 2. GVHD represents a significant risk in HSC transplantation beginning at the
first month posttransplantation.a. Acute GVHD presents as a sunburn-like rash, hepatosplenomegaly, jaun-
dice, elevated billirubin, and diarrhea.b. GVHD occurs when the recipient expresses HLA antigens not present on
the donor.
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Table 17–3. Diseases treated by hematopoietic stem cell transplantation.
Defects in Hematopoiesis Immune Deficiencies Malignancies
Sickle cell disease Severe combined Acute myeloid leukemiaimmune deficiency
Thalassemia Wiscott–Aldrich Acute lymphoblastic leukemiasyndrome
Aplastic anemia Leukocyte adhesion Chronic myelogenous leukemiadefect
Pure red cell aplasia Chediak–Higashi Multiple myelomasyndrome
Hyper-IgM syndrome
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c. GVHD requires donor T cells capable of responding to allogeneic HLA ofthe recipient.
d. GVHD is most evident when the recipient is immunosuppressed or geneti-cally incapable of rejecting donor T cells.
e. GVHD can be anticipated by tissue typing in the direction of donor anti-host.
3. Despite the negative effects of GVHD, donor T cells can also have a beneficialgraft-versus-tumor effect in malignant diseases.
4. The use of preconditioning regimens (eg, chemotherapy prior to transplanta-tion) and powerful immunosuppressive drugs increases the risks of oppor-tunistic infections. a. Depending on the degree of myeloablation, early infections can be severe
and can be caused by viruses, fungi, and bacteria.b. Common pathogens include cytomegalovirus, herpes simplex virus, Can-
dida albicans, and Aspergillus species.c. Neutrophil functions are generally restored first. d. Prophylactic therapies include antimicrobial agents, laminar flow rooms,
intravenous immunoglobulin (IVIG), and pediatric vaccines after lympho-cyte reconstitution.
VII. Posttransplantation immunosuppressive therapy primarily targets lym-phocyte activation, growth, and differentiation and inhibits inflammation(Table 17–4).
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Table 17–4. Immunosuppressive drugs used in transplantation.a
Agents Targets Clinical Use
Irradiation Many cells Conditioning for stem cell transplantation
Methotrexate, azathio- Many cells Organ transplantation, autoimmunityprine
Mycofenolate mofetil Lymphocytes Organ transplantation
Cyclosporine A (CsA), Lymphocytes Organ transplantationtacrolimus (FK506), sirolimus (rapamycin)
Corticosteroids Many cells Inflammatory diseases, organ transplanta-tion
OKT3 T cells Organ transplantation
ALG, ATG, daclizumab Lymphocytes Organ transplantation
aALG, antilymphocytic globulin; ATG, antithymocyte globulin.
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A. Cyclosporine and related drugs block calcineurin-dependent activation of nu-clear factor of activated T cells (NFAT) in T cells and inhibit cytokine (eg, IL-2)production (Chapter 6).
B. Azathioprine and methotrexate are cytotoxic to lymphocytes. 1. Azathioprine inhibits DNA synthesis.2. Methotrexate is a folate antagonist.3. The drugs are also used to treat autoimmune diseases (Chapter 16).
C. Antibodies against lymphocytes or their receptors block signaling and cause lym-phocyte death.1. OKT3 is an antibody to CD3 used in pancreas transplantation.2. Antilymphocyte globulin and antithymocyte globulin deplete T cells.3. Daclizumab is an antibody against the IL-2 receptor (CD25), which inhibits
lymphocyte proliferation. D. Corticosteroids inhibit inflammation (eg, neutrophil and macrophage activa-
tion) associated with graft destruction.E. Mycophenolate mofetil inhibits purine metabolism and blocks lymphocyte pro-
liferation. F. All of these drugs are essentially nonspecific in the sense that they inhibit protec-
tive immune responses while suppressing graft rejection.
CLINICAL PROBLEMSMary is a 52-year-old woman with end-stage renal disease secondary to diabetes. She re-ceived an allogeneic renal transplant 2 months ago and has progressed to a maintenancedose of immunosuppressive therapy. However, within the last week she has been experi-encing a progressive decline in renal function [decreased urine output, elevated blood ureanitrogen (BUN) and creatine] and currently has a temperature of 39°C. Her kidney is nowtender, painful, and swollen. A renal biopsy shows a dense interstitial mononuclear infil-tration.
1. Which of the following is most likely responsible for the change in her clinical courseover the past week?
A. An opportunistic viral infection
B. Renal toxicity due to her immunosuppressive drugs
C. Graft-versus-host disease
D. Acute allograft rejection
E. Diabetic nephropathy
Two months after having received an allogeneic stem cell transplant for the treatment ofacute lymphoblastic leukemia, a patient presented with diarrhea and a blistering, erythe-matous appearance to the skin of his anterior neck and back. Serum chemistry revealed el-evated liver enzymes and billirubin, and the liver and spleen appeared enlarged on physicalexamination.
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2. Which of the following diseases or pathogenic mechanisms is most likely causing thisclinical picture?
A. Rejection of the transplant
B. Autoantibody production against the patient’s lymphocytes
C. Deposition of immune complexes in the skin and liver
D. A reaction to his immunosuppressive drugs
E. Graft-versus-host disease
As a treatment for end-stage renal disease, xenotransplantation involves unique clinicalchallenges not seen in allotransplantation.
3. Which of the following mechanisms is more common in the rejection of renalxenografts than renal allografts?
A. Production of IgE antibodies
B. Activation of HLA class I-restricted CD4+ T cells
C. Binding of anti-HLA antibodies to donor tissues
D. Activation of complement by natural antibodies
E. Attraction of eosinophils into the graft
The HLA phenotypes of a family, including a patient who requires a kidney transplant,are listed below.
Family Member HLA-A Alleles HLA-B Alleles HLA-DR Alleles
Mother 1,7 8,12 4,5
Father 5,7 28,32 4,6
Daughter #1 1,7 8,32 5,6
Daughter #2 1,7 8,28 4,4
Son #1 1,5 12,28 4,5
Son #2 1,7 12,32 5,6
Patient 1,5 8,28 4,4
4. All other considerations being equal, which of the family members is best suited as thetransplant donor?
A. Daughter #1
B. Daughter #2
C. Mother
D. Son #1
E. Son #2
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5. Which of the donors above would be most appropriate to donate stem cells to the pa-tient if that were the indicated therapy?
A. Daughter #1
B. Daughter #2
C. Mother
D. Son #1
E. Son #2
ANSWERS
1. The correct answer is D. This is a typical description of acute renal allograft rejection.The histopathology confirms rejection, but does not fit a virus infection or diabeticnephropathy (hyaline thickening of the glomerular capillaries).
2. The correct answer is E. GVHD is common in allogeneic stem cell transplantation andinvolves the liver, spleen, gastrointestinal tract, and skin.
3. The correct answer is D. Although allografts can also undergo hyperacute rejection ini-tiated by isohemagglutinins, this rarely occurs due to the now routine use of the majorcross-match. Hyperacute rejection is currently the major initial barrier to successfulxenografting.
4. The correct answer is B. Daughter #2 has only a single disparity at one MHC class Ilocus. Particularly important in selecting a donor–recipient pair is avoiding disparitiesat both class I and class II loci.
5. The correct answer is B. The most important consideration in selecting a stem celldonor is avoiding GVHD, which is primarily induced by donor cells that recognizeHLA-D region alloantigens of the recipient. The second consideration in selecting adonor for stem cell transplantation is the survival of the graft, which is dictated by thesame rules that govern solid organ transplantation.
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Appendix I. CD markers and their functions.a
CD Marker Principal Functions
CD1 Presentation of glycolipids to NKT cells
CD3 Signaling chains of the TCR
CD4 Coreceptor for MHC class II-restricted T cells
CD8 Coreceptor for MHC class I-restricted T cells
CD11 α chain of the β2 integrin family
CD14 Nonsignaling component of the LPS receptor
CD18 β chain of the β2 integrin family
CD19 Signal transducer on B cells
CD20 Chain of the CR2 coreceptor
CD21 Chain of the CR2 coreceptor
CD25 α chain of the IL-2 receptor
CD28 Coreceptor on T cells that binds B7
CD34 Marker on hematopoietic stem cells
CD40 Coreceptor on B cells
CD45 Tyrosine phosphatase of T and B cells
CD55 Membrane decay accelerating factor
CD59 Membrane regulator of MAC assembly
CD80 B7-1 coreceptor on APCs
CD154 Ligand on T cells for CD40
aNKT, natural killer T; TCR, T cell receptor; MHC, major histocompatibility complex; LPS, lipopolysaccharide; IL, interleukin; MAC, membrane attack complex; APC, antigen-presenting cell.
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Appendix II. Cytokines.a
Cytokine Principal Functions
IL-1 α, β Similar to TNF-α; fever, leukocyte adhesion, lymphocyte costimulation
IL-2 T, B, and NK cell proliferation
IL-3 Proliferation of progenitor cells; growth factor for mast cells
IL-4 Differentiation of Th2 cells and B cells; Ig class switching to IgE.
IL-5 Differentiation of B cells and eosinophils; Ig class switching to IgA
IL-6 Hematopoiesis, acute phase response
IL-7 Progenitor B and T cell growth
IL-8 Chemotaxis of neutrophils
IL-10 Inhibits the Th1 pathway
IL-12 Coactivator of the Th1 pathway; induces IFN-γ production
IL-13 Ig class switching to IgE
IL-15 NK cell growth
IL-18 Coactivator for IFN-γ production
TGF-β Antiinflammatory; promotes wound healing; chemotaxis; Ig class switching to IgA
TNF-α Proinflammatory; neutrophil and endothelial cell activation; proapoptotic
IFN-α,β Inhibits viral replication; primes macrophages
IFN-γ Macrophage activation; inhibition of Th2 pathway
CSF-M Growth and differentiation of monocyte/macrophage lineage
CSF-G Growth and differentiation of granulocytes
CSF-GM Growth and differentiation of myeloid lineage cells
aIL, interleukin; TNF, tumor necrosis factor; NK, natural killer; Ig, immunoglobulin; IFN, interferon; TGF, transforming growth factor; CSF, colony-stimulating factor; M, macrophage; G, granulocyte.See also Table 12-3 for a list of important chemokines.
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ABO blood group systemantigens and antibodies, 35, 35f, 36ttransplantation across incompatibilities,
209Acquired immune deficiency syndrome
(AIDS), 187, 188tAcquired immunity. See Adaptive
immunityActivation-induced cytidine deaminase
(AID), 112, 181tActive immunization, 14ADA (adenosine deaminase), 182, 182tAdaptive immunity
clonal selection theory, 19–20, 20fdefinition, 1, 14features, 14vs. innate immunity, 15tlymphocyte functions. See
Lymphocyteslymphoid tissues and organs, 16–19primary vs. secondary response, 14–16,
15fresponse regulation, 10–11, 130–133
Addison’s disease, 199tAdenosine deaminase (ADA), 182, 182tAffinity, 52, 68Agammaglobulinemia, 106, 178Agar gel immunodiffusion, 56, 57fAID (activation-induced cytidine
deaminase), 112, 181tAIDS (acquired immune deficiency
syndrome), 187, 188tALG (antilymphocyte globulin), 212t,
213Allelic exclusion, 44–45Allergic rhinitis, 157Allergy(ies)
atopic. See Atopic allergyclinical manifestations and allergen
sources, 150, 150tdefinition, 149food, 149, 159prophylaxis, 157–158treatment, 157–159, 158t
Allografts, 204. See also RejectionALPS (autoimmune lymphoproliferative
syndrome), 122Altered peptide ligands, 79–80Anaphylactoid shock, 149Anaphylactoid syndrome, 160Anaphylaxis, 149, 156Anemia, 144, 198Anti-IgE, 158t
pathogenic mechanismsantireceptor autoantibodies, 196,
197tcell-mediated, 197t, 200–201cytotoxic immune tissue injury,
196–198, 197timmune complex-mediated, 197t,
198–200systemic, 195treatment, 200tWitebsky’s postulates, 194
Autoimmune hemolytic anemia, 28,196–198, 197t, 200t
Autoimmune lymphoproliferativesyndrome (ALPS), 122
Autoimmune orchitis, vasectomy and, 194Autoimmune polyendocrine syndrome
(APS), 195Autoimmunity. See also Autoimmune
diseasescomplement deficiencies and, 100, 187mechanisms, 133, 193
Autotolerance, 192–193Avidity, 52Azathioprine, 212t, 213
B7, 68t, 108fB cell(s)
anticytokine therapies for controllingactivation, 112
antigen-induced activation, 107, 108f,109–112
coreceptors, 110–111, 111t. See also Bcell receptor(s)
deficiency, 168t, 178t, 179, 182, 182tdifferentiation, 104–107, 105t, 106tinhibition of activation, 131, 132fselection, 105–106, 106tT cell activation and, 108f, 112, 124t
B cell receptor(s) (BCR)Ig expression, 46–49, 47fligands and biological responses, 111tsignaling pathways, 107, 108f,
109–112, 109t, 110fvs. T cell receptor, 21, 65
Bacteria, in immunocompromisedpatients, 168t
Bacteria, intracellular, 166t, 167Bare lymphocyte syndrome type 1
(BLS-1)clinical presentation, 84pathogenic mechanisms, 84, 122, 180,
181t
Antibody(ies). See also Immunoglobulin(s)affinity, 52avidity, 52deficiencies, 177t, 178–179, 178tin immune response to microbes, 167tnatural, 34–35reactions with antigens, 52–59, 53t,
54t. See also ImmunoassaysAntibody-mediated therapies, 37Anticytokine therapies, 112Antigen(s)
in differentiation of B cells, 107, 108f,109–112
presentation pathways, 84–87, 84t, 85fproperties, 28–29reaction with antibodies, 52–59, 53t,
54t. See also Immunoassaysrecognition by B cells and T cells, 29tT-independent, 112–113
Antigen-presenting cell (APC)in adaptive immune response
regulation, 22, 84–87, 130T cell receptor stimulation, 68, 68t,
124tAntigen receptor complexes, 21–24, 22f,
23fAntigenic drift, 169Antigenic shift, 169Antigenicity, 28Antihistamines, 158t, 159Antilymphocyte globulin (ALG), 212t,
213Antithymocyte globulin (ATG), 212t, 213AP-1, 70, 110APC. See Antigen-presenting cellAPS (autoimmune polyendocrine
syndrome), 195Asthma, allergic, 157ATG (antithymocyte globulin), 212t, 213Atopic allergy
characteristics, 149diagnosis, 157pathogenic mechanisms, 133, 152–157prophylaxis, 157–159treatment, 157–159, 158t
Autografts, 204Autoimmune diseases. See also
Autoimmunitycriteria, 194diagnosis, 194–195epidemiology, 199tinfection and, 198organ-specific, 195
INDEX
Note: Page numbers followed by f or t indicate figures or tables, respectively.
219
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Bare lymphocyte syndrome type 2 (BLS-2)
clinical presentation and treatment, 84,177t
differential diagnosis, 122pathogenic mechanisms, 84, 122, 181,
181tBCR. See B cell receptor(s)Bence-Jones proteins, 36β2- agonists, 158tβ2- microglobulin, 78–79, 78f, 82f, 84tBiclonal myeloma, 46Bispecific antibodies, 37Blood transfusions, 35, 159, 206tBLS-1. See Bare lymphocyte syndrome
type 1BLS-2. See Bare lymphocyte syndrome
type 2Bruton’s tyrosine kinase, 105t, 106, 179
Calcineurin, 69, 109tCandidiasis, oral, 120–121, 168tCD markers, 24t, 25, 217CD3 deficiency, 64, 180, 181tCD4+CD25+ regulatory T (Treg) cells. See
Regulatory T (Treg) cellsCell adhesion molecules, 123, 183CGD. See Chronic granulomatous diseaseChediak-Higashi syndrome
genetic defect, 126, 184pathogenic mechanisms, 184, 184t
Chemokinesfunctions, 144–145, 144t, 218properties, 141
Chronic granulomatous disease (CGD),5–6, 184t, 185
Clonal anergy, 192Clonal deletion, 192Clonal selection theory, 19–20, 21f, 49tCluster of differentiation (CD) scheme.
See CD markersColony-stimulating factor for granulocytes
(CSF-G), 16, 218Common γ chain (γc), 182, 182tCommon variable immune deficiency,
188Complement receptors (CR), 98, 98t, 99fComplement system
activationalternative pathway, 92t, 93f, 94–95classical pathway, 91–93, 92t, 93fcontrol, 95–96core elements, 92flectin pathway, 92t, 93–94, 93fterminal steps, 95, 95f
components and complexes, 97–99,97t
deficienciesautoimmunity and, 100, 187common infections with, 99–100,
168t, 186, 186tprimary, 99–100, 185–186, 186ttreatment, 187
Desensitization, 158Diabetes mellitus type I
epidemiology, 199tpathogenic mechanisms, 197t,
200–201treatment, 200t
Diacylglyceride (DAG), 69, 110DiGeorge syndrome
clinical manifestations, 177t, 180, 181tpathogenic mechanisms, 17, 177t, 180
DNA vaccines, 172
EIA. See Enzyme-linked immunosorbentassay
Elicitation, in adaptive immune response,150, 152f
ELISA. See Enzyme-linkedimmunosorbent assay
Endothelium, 2tEnzyme-linked immunosorbent assay
(ELISA), 58Epinephrine, 158t, 159Epithelial cells, 7Epitope spreading, 195–196, 196fErythroblastosis fetalis, 55, 131Erythropoietin, 144
Factor I deficiency, 97–98Fas, 73, 74fFcεRI, 153–154, 154fFcγRIIB, 131, 132fFibrinolysis system, 2t, 10Flow cytometry, 58–59, 59f, 60fFood allergies, 159Fungi, in immunocompromised patients,
167t, 168t
γc chain deficiency, 146, 176f, 182, 182t
γ-globulins. See Immunoglobulin(s)γδ T cells
vs. conventional T cells, NKT cells,and NK cells, 125t
properties, 125Gell and Coombs classification, 150, 151tGene therapy, 183Germinal center, 18, 18f, 107Goodpasture’s disease, 194, 197t, 198Graft-versus-host disease (GVHD)
in hematopoietic stem celltransplantation, 211–212
in pregnancy, 180Granzyme, 73Grave’s disease
epidemiology, 199tpathogenic mechanisms, 196, 197ttreatment, 200t
GVHD. See Graft-versus-host disease
Haemophilus influenzae type B (Hib),vaccine, 34, 170t
Haplotype, 82Hapten, 28, 153
in disease pathogenesis, 99–100functions, 91inflammatory effects, 2t, 10innate immune effects, 2t, 9–10receptors, 98, 98t, 99fregulation, 95–96, 96t
Conjugate vaccines, 34, 171, 172tContact dermatitis, 161Convertases, 91, 92tCoombs test, 28, 55, 197Coreceptors, in B cell activation,
110–111, 111tCoreceptors, in T cell activation, 123Corneal transplants, 206Corticosteroids, 158t, 159, 212t, 213CR. See Complement receptorsCrohn’s disease
epidemiology, 199tpathogenic mechanisms, 151–152,
197ttreatment, 200t
Cross-match, 55, 208Cross-reactivity, 52–53, 53t, 204, 205fCryoglobulinemia, 36CSF-G (colony-stimulating factor for
granulocytes), 16, 218CTL. See Cytotoxic T lymphocyteCyclic neutropenia, 16, 17t, 183Cyclosporine, 70, 212t, 213Cytokine(s). See also Chemokines;
Interferon(s); Appendix IIin adaptive immune response,
142–143, 157in allograft rejection, 208in amplification of biological response,
138, 139fin control of adaptive immune
responses, 130in danger signaling response, 8, 9t,
140–141functions, 137–138in hematopoiesis, 143–144, 143fin innate immune response, 2t,
139–142, 140tproinflammatory effects, 140–141,
140treceptors. See Cytokine receptorsredundant effects, 137, 138tin response to infection, 134, 167–168
Cytokine receptors, 107, 123, 145–146,145t
Cytotoxic T lymphocyte (CTL)in allograft rejection, 207f, 208in immune response to infectious
agent, 166t, 167t, 168properties, 72–73, 73t, 74f
Daclizumab, 212t, 213Danger signaling, 7–8, 9t, 10–11Decay accelerating factor (DAF), 95, 96t,
97Defensins, 4, 7Dendritic cells, 124t
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Hashimoto’s thyroiditisepidemiology, 199tpathogenic mechanisms, 197ttreatment, 200t
Hay fever, 157Heart transplantation, 206t, 209Hemagglutination, 55Hematopoiesis, 16, 143f, 176fHematopoietic stem cell, 17, 176fHematopoietic stem cell transplantation,
206t, 211–212, 211tHemolytic anemia, autoimmune. See
Autoimmune hemolytic anemiaHemolytic disease of the newborn, 131Hereditary angioedema, 10, 93Hereditary hemochromatosis, 87, 88tHib. See Haemophilus influenzae type BHistamine, inflammatory effects,
155–156, 155tHuman leukocyte antigen (HLA)
disease associations, 87–88, 88tgene expression patterns, 81–84, 81f,
83f, 83tgenetic map, 82fheterodimers, 78f, 82finheritance, 82–83, 83fpolymorphism, 80, 81tstructure, 78–79, 78fin transplantation, 204, 205f,
209–210, 209ttyping, 209, 209t
Humoral immunity, cytokines in, 142Hybridoma antibodies, 37Hyper-IgE syndrome. See Job’s syndromeHyper-IgM syndrome
clinical presentation, 177tgenetic defect, 111–112, 177tpathogenic mechanisms, 68, 181, 181t
Hypergammaglobulinemia, 57Hypersensitivity. See Allergy(ies) and
Immune response, tissue injurycaused by
Hypogammaglobulinemia, 132, 179
IFN. See Interferon(s)Ig. See Immunoglobulin(s)IgA deficiency, selective. See Selective IgA
deficiencyIgG2 deficiency, selective. See Selective
IgG2 deficiencyIi chain, 87Interleukin-1 receptor-associated kinase
(IRAK), 187Immune complex, 54, 197t, 198–199Immune deficiencies
gene therapy, 183phagocytic cells. See Phagocytic cell
deficiencyprimary
antibody. See Antibody(ies),deficiencies
clinical presentation, 175diagnosis, 99, 179, 183
heterogeneity, 30–31, 35–36intravenous, 29, 179isotype characteristics, 30–31, 32tisotype switching, 34, 47–48, 48f, 72,
112, 142monoclonal, 36–37polymeric, 33fproperties, 29, 30fstructure and function, 29–34
Immunoglobulin A (IgA)properties, 32–33, 32tsecretory, 33, 113–115, 113f, 114fselective deficiency, 114, 178–179, 178t
Immunoglobulin D (IgD), 32tImmunoglobulin E (IgE), 32t, 152, 152fImmunoglobulin G (IgG)
G2 subclass deficiency, 113properties, 32tstructure, 30, 31f
Immunoglobulin M (IgM)in natural antibodies, 34–35properties, 31, 32t, 33f
Immunoprecipitation, 55–56, 56fImmunosuppressive drugs, 212–213, 212tImmunotherapy, 157–158Immunotoxins, 37Immunotyrosine activation motif
(ITAM), 109Infectious diseases, worldwide rates, 165Inflammatory system, 2tInfluenza A, 169Inhibitor κB (IκB), 70f, 109tInnate immunity
vs. adaptive immunity, 15tcharacteristics, 1components, 2tdanger signaling, 7–10first lines of defense, 1–2leukocyte functions, 4–7, 5f, 6fpathogen-associated molecular patterns
(PAMP), 3response regulation, 130
Interferon(s) (IFN)activities, 9, 218type I (IFN-α/β), 141type II (IFN-γ)
characteristics, 141–142deficiency, 142functions, 140t, 141opportunistic infections and, 9
Interleukin-1 (IL-1), 140tInterleukin-1β (IL-1β)
functions, 140t, 141redundancy with TNF-α, 138t
Interleukin-2 (IL-2)characteristics, 142functions, 140t, 142
Interleukin-4 (IL-4), 142, 152fInterleukin-5 (IL-5), 142Interleukin-6 (IL-6), 140tInterleukin-8 (IL-8), 140tInterleukin-10 (IL-10), 132–133, 140t,
141
examples, 176f, 177tfeatures, 178–179, 178t, 181t, 182t,
184tT cell. See T cell(s), deficiencytreatment, 179, 183, 187
secondaryclinical presentation, 187–188opportunistic infections in. See
Opportunistic infectionspathophysiology, 187–188
Immune response(s)to infection
characteristics, 164–165mechanisms, 165–168, 166tby microbe type, 165, 167tmicrobial evasion mechanisms,
169–170tissue injury caused by
characteristics, 149–151classification, 150, 151tmechanisms, 150–151phases, 150–151, 152ftype I, 151t, 152–158, 154f, 155ttype II, 151t, 159–160type III, 151t, 160type IV, 151t, 160–161
Immune systemadaptive (acquired). See Adaptive
immunitydysregulation, 133–134. See also specific
conditionsgene polymorphisms and, 133homeostatic regulation, 130–133innate. See Innate immunity
Immunization. See also Vaccine(s)active. See Active immunizationpassive. See Passive immunization
Immunoassaysagar gel immunodiffusion, 56, 57fapplications, 54tenzyme-linked immunosorbent assay,
58hemagglutination, 55immunoblotting, 58immunofixation, 56, 57fimmunofluorescence assays, 58–59,
59f, 60fimmunoprecipitation, 55–56, 56fradioimmunoassays, 58
Immunoblotting, 58Immunofixation, 56, 57fImmunofluorescence assays, 58–59, 59f,
60fImmunogenicity, 28Immunoglobulin(s) (Ig)
abnormal synthesis and cryopathies, 36diversity, 45–49, 45t, 81tgene expression
chromosomal translocations, 43germ line configuration, 40, 41, 41flocus deletions, 41Rag deficiency, 42recombination, 41–45, 42f, 44f
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Interleukin-12 (IL-12), 141Intracellular killing, 165, 166t, 167Intravenous immunoglobulin (IVIG)
for B cell deficiencies, 179for multiple myeloma, 132in selective IgA deficiency, 179–180therapeutic uses, 29
Isografts, 204Isohemagglutinins, 35, 35f, 36tIsotype switching, 34, 47–48, 48f, 72,
112, 142IVIG. See Intravenous immunoglobulin
Jak/STAT signaling, 145Jak3 gene, 182, 182tJob’s syndrome
clinical manifestations, 153, 184–185,184t
pathogenic mechanisms, 153
Kidney transplantation, 206tKilled vaccines, 172t
Lck tyrosine kinase, 71Leukemia, phenotyping, 59Leukocyte adhesion defect (LAD)
clinical manifestations, 183–184, 184t
pathogenic mechanisms, 100, 100t,183–184, 184t
Leukocyteschemotactic factor recognition, 4tcongenital deficiencies, 17t, 183–185in innate immunity, 4–7normal levels, 17t
Leukotriene(s) (LTs), 156Leukotriene receptor antagonists, 158tLipid mediators, 156Lipopolysaccharide (LPS), 7, 8f, 134Live attenuated vaccines, 171, 172tLiver transplantation, 206tLung transplantation, 206tLymph node(s), 18, 18f, 19tLymphocytes. See also T cell(s)
antigen receptors, 21–24, 22f, 23f, 46,64–67
cell surface molecules, 24–25, 217chemotactic factors, 4tcongenital deficiencies, 17t, 176f,
178–183development, 16–119normal levels, 17trecirculating pool, 19, 20f
Lymphoid organs, 16–20, 18fLymphoma, phenotyping, 59Lysosomal trafficking regulator (LYST),
126
M cell, 114f, 115M proteins, 30MAC (membrane attack complex), 95,
95f
as source of proinflammatorycytokines, 139–140, 139f
Natural killer T (NKT) cellsvs. conventional T cells, γδ T cells, and
NK cells, 125tphysiology, 7properties, 73t, 126as source of proinflammatory
cytokines, 139–140, 139fTCR expression, 67
Negative selection, 105t, 106–107, 106t,119t, 122
Neutropeniacyclic, 16, 17tsevere congenital, 16
Neutrophil(s), 167tNeutrophil granules
chemotactic factors, 4tinflammatory effects, 2tinnate immune effects, 2t, 4
Nitric oxide, 6NK cells. See Natural killer (NK) cellsNKT cells. See Natural killer T (NKT)
cellsNonsteroidal anti-inflammatory drugs
(NSAIDs), 158t, 200tNuclear factor κB (NFκB), 69, 70f, 110,
110f, 145t, 154Nuclear factor of activated T cells
(NFAT), 69, 70f, 110, 110f, 154,155t
OKT3, 212t, 213Opportunistic infections
in AIDS, 188tcharacteristics, 175common types and mechanisms,
168–169, 168tin hematopoietic stem cell
transplantation, 212IFN-γ and, 9
Opsonophagocytosis, 4, 5f, 165, 166t
PAF (platelet activating factor), 156PAMP (pathogen-associated molecular
pattern), 3Pancreas transplantation, 206tParoxysmal nocturnal hemoglobinuria
(PNH), 100, 186Passive immunization, 15, 16Patch test, 161Pathogen-associated molecular pattern
(PAMP), 3Pemphigus vulgaris, 197t, 199tPenicillin, 28Peptides, altered ligands in, 79–80Perforin, 73, 74fPernicious anemia, 21, 197tPeyer’s patches, 114f, 115PGs (prostaglandins), 154f, 156Phagocytic cell deficiency
common infections with, 168t
Macrophagesin allograft rejection, 208chemotactic factors, 4tin immune response to microbes, 167tT cell activation and, 124t
Major histocompatibility complex(MHC). See also Humanleukocyte antigen
in antigen presentation, 84–87, 84t,85f
deficiencies, 122, 180–181diversity, 80–81, 81tfunctions, 77genetic map, 82fstructure, 78–79, 78fin T cell differentiation, 121–122in transplantation, 77, 204, 205f, 209t
Mannose-binding lectin (MBL), 92t, 94Mannose-binding protein (MBP), 3, 94Mast cell(s)
FcεRI signaling, 153–154, 154fIgE-independent activation, 155inflammatory mediators from,
155–157, 155tMast cell stabilizers, 158tMBP (mannose-binding protein), 3Membrane attack complex (MAC), 95,
95fMembrane lysis, 95, 165, 166tMethotrexate, 212t, 213MHC. See Major histocompatibility
complexMicrobes
immune evasion mechanisms, 169–170immune response. See Immune re-
sponse(s)worldwide infection rates, 165
Mixed lymphocyte reaction (MLR), 210,210f
Monoclonal antibodies, 36–37, 112Monoclonal gammopathies, 36–37, 57,
57fMPO (myeloperoxidase) deficiency, 185Mucosal immunity, 113–115Multiple myeloma
IVIG therapy, 132pathogenic mechanisms, 29–30, 46serum protein electrophoresis, 30f, 31
Multiple sclerosis, 194, 197t, 200Myasthenia gravis, 196, 197t, 199tMycophenolate mofetil, 212t, 213Myeloperoxidase (MPO) deficiency, 185
Natural antibodies, 34–35Natural killer (NK) cells
in allograft rejection, 208vs. conventional T cells, γδ T cells, and
NKT cells, 125tin immune response to infectious
agent, 166t, 167t, 168physiology, 7properties, 73t, 126
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N
features, 183–185, 184ttreatment, 185
Phagocytosis. See OpsonophagocytosisPlatelet activating factor (PAF), 156PNH (paroxysmal nocturnal
hemoglobinuria), 100, 186Polio vaccine, 115, 170tPolyclonal gammopathies, 57Poly Ig receptor, 113Polyvalent vaccines, 171, 172, 172tPositive selection, 105, 105t, 119t, 120t,
121Pregnancy, immunological considerations,
55, 133, 180Prostaglandin(s) (PGs), 154f, 156
Radioimmunoassays, 58Rag genes
characteristics, 41–42deficiency, 42, 182, 182texpression of, 104, 105t, 119–120,
119tReactive oxygen intermediates, 5Regulatory T (Treg) cells
in immune homeostasis regulation,132–133
in tolerance, 192Rejection
hyperacute, 211immune mediators, 206–208, 207fpathogenic mechanisms, 208prevention methods, 208–210, 209t,
210f, 212–213, 212tRespiratory burst, 5–6, 6fRespiratory burst oxidase, 5–6Rh disease, 55, 131Rheumatic fever, 133, 197tRheumatoid arthritis
pathogenic mechanisms, 197t,199–200
treatment, 200ttuberculosis in, 138–139
Rheumatoid factor (RF), 195Rhogam, 131
SCID. See Severe combined immunedeficiency
Secretory component, 33, 33f, 113Selective IgA deficiency, 177t, 178–179Selective IgG2 deficiency, 178t, 179Sensitization, in adaptive immune
response, 150, 152fSepsis, 8, 134, 134fSeroconversion, 164Serum protein electrophoresis, 30fSerum sickness, 160, 197t, 198Severe combined immune deficiency
(SCID)clinical manifestations and treatment,
42, 118
TI (T-independent) antigens, 112–113Tissue typing, 208–210, 209tTLR family. See Toll-like receptor (TLR)
familyTNF-α. See Tumor necrosis factor-αTolerance, 192–193Toll-like receptor (TLR) family
in danger signaling, 7, 8fin innate immunity, 3–4, 3t
Toxic shock syndrome, 67Toxin neutralization, 166t, 167Transfusion reaction, 159Transient hypogammaglobulinemia of
infancy, 178t, 179Transplantation
cyclosporine and, 70, 212t, 213hematopoietic stem cell, 183, 211–212,
211timmunosuppressive therapy, 212–213,
212tMHC and, 77, 204–205, 205fprinciples, 204–205rejection. See Rejectionspecial considerations by type, 206tbetween species, 96–97, 210–211tolerance, 193waiting lists, 210
Transporter associated with antigen proces-sing (TAP), 85f, 86, 170, 180
Treg cells. See Regulatory T (Treg) cellsTumor necrosis factor-α (TNF-α)
functions, 140, 140t, 218redundancy with IL-1β, 138t
Tumor necrosis factor-β (TNF-β), 140t
Vaccine(s)characteristics, 170–171design and use, 171novel strategies, 172parenteral vs. mucosal, 115polio, 115recommendations for children, 170t,
171types, 171, 172t
Vasectomy, autoimmune orchitis and, 194Virus(es)
in immunocompromised patients, 168tneutralization, 166t, 167
Western blotting, 58Wiscott-Aldrich syndrome, 182Witebsky’s postulates, 194
X-linked agammaglobulinemia (XLA),106, 178t, 179
Xenografts, 204Xenotransplantation, 96–97, 210–211
ZAP-70, 69, 180, 181tζ chain, 22f, 64–65, 69f
genetic defects in, 42, 118, 146, 182,182t
SIRS (systemic inflammatory responsesyndrome), 141
Sjögren’s syndrome, 197t, 199t, 201SLE. See Systemic lupus erythematosusSomatic hypermutation, 46, 67, 107Spleen, 19tSpondyloarthropathies, 87–88, 88tSubunit vaccines, 171, 172tSuperantigens, 67Superoxide, 5, 6fSwitch recombinase deficiency, 112, 181tSystemic inflammatory response syndrome
(SIRS), 141Systemic lupus erythematosus (SLE)
clinical manifestations and treatment,198–199, 200t
epidemiology, 199tpathogenic mechanisms, 197t, 199
T cell(s)activation, 68, 123–126, 124tadhesion molecules and coreceptors,
68, 68tconventional, vs. γδ T cells, NKT cells,
and NK cells, 125tcytotoxic. See Cytotoxic T lymphocytedeficiency
common infections with, 168tdiagnosis, 183features, 177t, 180–182, 181ttreatment, 183
differentiation, 118–122, 119treceptors. See T cell receptor(s)Th1 and Th2 CD4+ subsets, 71–72,
71t, 72f, 124T cell receptor(s) (TCRs)
altered peptide ligands, 79–80vs. B cell receptor, 65tCD3 expression and, 22f, 23, 64costimulation by APC, 68, 68tMHC receptors and thymic selection,
121–122rearrangements in cancer, 67signaling events, 69–71, 69f, 70fsignaling pathways, 109tstructure, 64–67, 65f, 66f, 66tsubsets, 119–120, 120t
T helper (Th) cells, 71–72, 71t, 72f, 107,108f, 124
deficiency, 181, 181tin immune response to microbes, 167t
T-independent (TI) antigens, 112–113TCRs. See T cell receptor(s)Th cells. See T helper (Th) cellsThrombocytopenia purpura, 194, 197tThrush, 120–121Thymic apoptosis, defective, 122Thymocytes, 119–120, 120t, 121f
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